Human Transcriptomes

ABSTRACT

Global gene expression patterns have been characterized in normal and cancerous human cells using serial analysis of gene expression (SAGE). Cancer cell-specific, cell-type specific, and ubiquitously expressed genes have been identified. This information can be used to provide combinations of cell type-and cancer-specific gene probes, as well as methods of using these probes to identify particular cell types, screen for useful drugs, reduce cancer-specific gene expression, standardize gene expression, and restore function to a diseased cell or tissue.

[0001] This application is a continuation of co-pending application Ser. No. 09/448,480 filed Nov. 24, 1999, which is incorporated herein by reference in its entirety.

[0002] This invention was made with government support under CA57345, CA62924, and CA43460 awarded by the National Institutes of Health. The government has certain rights in the invention.

BACKGROUND OF THE INVENTION

[0003] The characteristics of an organism are largely determined by the genes expressed within its cells and tissues. These expressed genes can be represented by transcriptomes that convey the identity and expression level of each expressed gene in a defined population of cells (1, 2). Although the entire sequence of the human genome will be elucidated in the near future (3), little is known about the many transcriptomes present in the human organism. Basic questions regarding the set of genes expressed in a given cell type, the distribution of expressed genes, and how these compare to genes expressed in other cell types, have remained largely unanswered.

[0004] General properties of gene expression patterns in eukaryotic cells were determined many years ago by RNA-cDNA reassociation kinetics (4), but these studies did not provide much information about the identities of the expressed genes within each expression class. Technological constraints have limited other analyses of gene expression to one or few genes at a time (5-9) or were non-quantitative (10, 11). Serial analysis of gene expression (SAGE) (12), one of several recently developed gene expression methods, has permitted the quantitative analysis of transcriptomes in the yeast Saccharomyces cereviseae (1, 13). This effort identified the expression of known and previously unrecognized genes in S. cereviseae (1, 14) and demonstrated that genome-wide expression analyses were practicable in eukaryotes.

[0005] Thus, there is a need in the art for the identification of transcriptomes which represent gene expression in particular cell types or under particular physiological conditions in eukaryotes, particularly in humans.

SUMMARY OF THE INVENTION

[0006] It is an object of the present invention to provide such transcriptomes, individual polynucleotides, and methods of using the polynucleotides to identify particular cell types, screen for useful drugs, reduce cancer-specific gene expression, standardize gene expression, and restore function to a diseased cell or tissue. These and other objects of the invention are provided by one or more of the embodiments described below.

[0007] One embodiment of the invention is a method of identifying a cell as either a colon epithelial cell, a brain cell, a keratinocyte, a breast epithelial cell, a lung epithelial cell, a melanocyte, a prostate cell, or a kidney epithelial cell. Expression in a test cell of a gene product of at least one gene is determined. The at least one gene comprises a sequence selected from at least one of the following groups:

[0008] (a) the sequences shown in SEQ ID NOS:2, 5-18, 20-84, and 85;

[0009] (b) the sequences shown in SEQ ID NOS:87-96, 98, 100-103, 105, 107-110, 112-129, 131-150, and 151;

[0010] (c) the sequences shown in SEQ ID NOS:152-154 and 155;

[0011] (d) the sequences shown in SEQ ID NOS:156-159 and 160;

[0012] (e) the sequences shown in SEQ ID NOS:161-166 and 167;

[0013] (f) the sequences shown in SEQ ID NOS:168, 170, 172-177, 179-188, 190-207, and 208;

[0014] (g) the sequences shown in SEQ ID NOS:209 and 210; and

[0015] (h) the sequences shown in SEQ ID NOS:211-224 and 225. Expression of a gene product of at least one gene comprising a sequence shown in (a) identifies the test cell as a colon epithelial cell. Expression of a gene product of at least one gene comprising a sequence shown in (b) identifies the test cell as a brain cell. Expression of a gene product of at least one gene comprising a sequence shown in (c) identifies the test cell as a keratinocyte. Expression of a gene product of at least one gene comprising a sequence shown in (d) identifies the test cell as a breast epithelial cell. Expression of a gene product of at least one gene comprising a sequence shown in (e) identifies the test cell as a lung epithelial cell. Expression of a gene product of at least one gene comprising a sequence shown in (f) identifies the test cell as a melanocyte. Expression of a gene product of at least one gene comprising a sequence shown in (g) identifies the test cell as a prostate cell. Expression of a gene product of at least one gene comprising a sequence shown in (h) identifies the test cell as a kidney epithelial cell.

[0016] Another embodiment of the invention is an isolated polynucleotide comprising a sequence selected from the group consisting of SEQ ID NOS:2, 5, 6, 8, 10, 12, 13, 15, 17, 18, 21, 24-26, 28, 30, 31, 34-36, 38, 40, 47-51, 53-57, 59-62, 65-69, 71-76, 78, 80-84, 98, 103, 113, 115, 122, 129, 132, 134, 135, 140, 144, 149, 150, 153-168, 174-176, 182, 185, 186, 188, 190, 200, 201, 205-213, 216-224, 237, 239, 257, 263, 485, 487, 495, 499, 514, 586, 686, 751, 835, 844, 878, 910, 925, 932, 951, 1000, 1005, 1070, 1122, 1130, 1170, 1173, 1187, 1189, 1200, 1213, 1220, 1237, 1257, 1264, 1273, 1293, 1300, 1320, 1367, 1371, 1401, 1403, 1404, 1406, 1418, and 1419.

[0017] Still another embodiment of the invention is a solid support comprising at least one polynucleotide. The polynucleotide comprises a sequence selected from at least one of the following groups:

[0018] (a) the sequences shown in SEQ ID NOS:2, 5, 6, 8, 10, 12, 13, 15, 17, 18, 21, 24-26, 28, 30, 31, 34-36, 38, 40, 47-51, 53-57, 59-62, 65-69, 71-76, 78, 80-83, and 84;

[0019] (b) the sequences shown in SEQ ID NOS:98, 103, 113, 115, 122, 129, 132, 134, 135, 140, 144, 149, and 150;

[0020] (c) the sequences shown in SEQ ID NOS:153-154 and 155;

[0021] (d) the sequences shown in SEQ ID NOS:156-157 and 160;

[0022] (e) the sequences shown in SEQ ID NOS:161-166 and 167;

[0023] (f) the sequences shown in SEQ ID NOS:168, 174-176, 182, 185, 186, 188, 190, 200, 201, 205-207 and 208;

[0024] (g) the sequences shown in SEQ ID NOS:209 and 210;

[0025] (h) the sequences shown in SEQ ID NOS:211-213, 216-223, and 224;

[0026] (i) the sequences shown in SEQ ID NOS:237, 239, 257, and 263; or

[0027] (j) the sequences shown in SEQ ID NOS:485, 487, 495, 499, 514, 586, 686, 751, 835, 844, 878, 910, 925, 932, 951, 1000, 1005, 1070, 1122, 1130, 1170, 1173, 1187, 1189, 1200, 1213, 1220, 1237, 1257, 1264, 1273, 1293, 1300, 1320, 1367, 1371, 1401, 1403, 1404, 1406, 1418, and 1419.

[0028] Even another embodiment of the invention is a method of identifying a test cell as a cancer cell. Expression in a test cell of a gene product of at least one gene is determined. The at least one gene comprises a sequence selected from the group consisting of SEQ ID NOS:228, 230-257, 259-260, and 262-265. An increase in expression of at least two-fold relative to expression of the at least one gene in a normal cell identifies the test cell as a cancer cell.

[0029] Yet another embodiment of the invention is a method of reducing expression of a cancer-specific gene in a human cell. A reagent which specifically binds to an expression product of a cancer-specific gene is administered to the cell. The cancer-specific gene comprises a sequence selected from the group consisting of SEQ ID NOS:228, 230-257, 259-260, and 262-265. Expression of the cancer-specific gene is thereby reduced relative to expression of the cancer-specific gene in the absence of the reagent.

[0030] Even another embodiment of the invention is a method for comparing expression of a gene in a test sample to expression of a gene in a standard sample. A first ratio and a second ratio are determined. The first ratio is an amount of an expression product of a test gene in a test sample to an amount of an expression product of at least one gene comprising a sequence selected from the group consisting of SEQ ID NOS:266-375, 377-652, 654-796, and 798-1448 in the test sample. The second ratio is an amount of an expression product of the test gene in a standard sample to an amount of an expression product of the at least one gene in the standard sample. The first and second ratios are compared. A difference between the first and second ratios indicates a difference in the amount of the expression product of the test gene in the test sample.

[0031] Still another embodiment of the invention is a method of screening candidate anti-cancer drugs. A cancer cell is contacted with a test compound. Expression of a gene product of at least one gene in the cancer cell is measured. The at least one gene comprises a sequence selected from the group consisting of SEQ ID NOS:228, 230-257, 259, 260, 262-263, and 265. A decrease in expression of the gene product in the presence of a test compound relative to expression of the gene product in the absence of the test compound identifies the test compound as a potential anti-cancer drug.

[0032] Still another embodiment of the invention is a method of screening test compounds for the ability to increase an organ or cell function. A selected from the group consisting of a colon epithelial cell, a brain cell, a keratinocyte, a breast epithelial cell, a lung epithelial cell, a melanocyte, a prostate cell, and a kidney cell is contacted with a test compound. Expression in the cell of a gene product of at least one gene is measured. The gene comprises a sequence selected from at least one of the following groups:

[0033] (a) the sequences shown in SEQ ID NOS:2, 5-18, 20-84, and 85;

[0034] (b) the sequences shown in SEQ ID NOS:87-96, 98, 100-103, 105, 107-110, 112-129, 131-150, and 151;

[0035] (c) the sequences shown in SEQ ID NOS:152-154 and 155;

[0036] (d) the sequences shown in SEQ ID NOS:156-159 and 160;

[0037] (e) the sequences shown in SEQ ID NOS:161-166 and 167;

[0038] (f) the sequences shown in SEQ ID NOS:168, 170, 172-177, 179-188, 190-207 and 208;

[0039] (g) the sequences shown in SEQ ID NOS:209 and 210; and

[0040] (h) the sequences shown in SEQ ID NOS:211-224 and 225. An increase in expression of a gene product of at least one gene comprising a sequence shown in (a) identifies the test compound as a potential drug for increasing a function of a colon cell. An increase in expression of a gene product of at least one gene comprising a sequence shown in (b) identifies the test compound as a potential drug for increasing a function of a brain cell. An increase in expression of a gene product of at least one gene comprising a sequence shown in (c) identifies the test compound as a potential drug for increasing a function of a skin cell. An increase in expression of a gene product of at least one gene comprising a sequence shown in (d) identifies the test compound as a potential drug for increasing a function of a breast cell. An increase in expression of a gene product of at least one gene comprising a sequence shown in (e) identifies the test compound as a potential drug for increasing a function of a lung cell. An increase in expression of a gene product of at least one gene comprising a sequence shown in (f) identifies the test compound as a potential drug for increasing a function of a melanocyte. An increase in expression of a gene product of at least one gene comprising a sequence shown in (g) identifies the test compound as a potential drug for increasing a function of a prostate cell. An increase in expression of a gene product of at least one gene comprising a sequence shown in (h) identifies the test compound as a potential drug for increasing a function of a kidney cell.

[0041] Yet another embodiment of the invention is a method to restore function to a diseased tissue. A gene is delivered to a diseased cell selected from the group consisting of a colon epithelial cell, a brain cell, a keratinocyte, a breast epithelial cell, a lung epithelial cell, a melanocyte, a prostate cell, and a kidney cell. The gene comprises a nucleotide sequence selected from at least one of the following groups:

[0042] (a) the sequences shown in SEQ ID NOS:2, 5-18, 20-84, and 85;

[0043] (b) the sequences shown in SEQ ID NOS:87-96, 98, 100-103, 105, 107-110, 112-129, 131-150, and 151;

[0044] (c) the sequences shown in SEQ ID NOS:152-154 and 155;

[0045] (d) the sequences shown in SEQ ID NOS:156-159 and 160;

[0046] (e) the sequences shown in SEQ ID NOS:161-166 and 167;

[0047] (f) the sequences shown in SEQ ID NOS:168, 170, 172-177, 179-188, 190-207, and 208;

[0048] (g) the sequences shown in SEQ ID NOS:209 and 210; and

[0049] (h) the sequences shown in SEQ ID NOS:211-224 and 225. Expression of the gene in the diseased cell is less than expression of the gene in a corresponding cell which is normal. If the diseased cell is a colon epithelial cell, then the nucleotide sequence is selected from (a). If the diseased cell is a brain cell, then the nucleotide sequence is selected from (b). If the diseased cell is a keratinocyte, then the nucleotide sequence is selected from (c). If the diseased cell is a breast epithelial cell, then the nucleotide sequence is selected from (d). If the diseased cell is a lung epithelial cell, then the nucleotide sequence is selected from (e). If the diseased cell is a melanocyte, then the nucleotide sequence is selected from (f). If the diseased cell is a prostate cell, then the nucleotide sequence is selected from (g). If the diseased cell is a kidney cell, then the nucleotide sequence is selected from (h).

[0050] Thus, the invention provides transcriptomes, polynucleotides, and methods of identifying particular cell types, reducing cancer-specific gene expression, identifying cancer cells, standardizing gene expression, screening test compounds for the ability to increase an organ or a cell function, and restoring function to a diseased tissue.

BRIEF DESCRIPTION OF THE DRAWINGS

[0051]FIG. 1. Sampling of gene expression in colon cancer cells. Analysis of transcripts at increasing increments of transcript tags indicates that the fraction of new transcripts identified approaches 0 at approximately 650,000 total tags.

[0052]FIG. 2. Colon cancer cell Rot curve.

[0053] FIGS. 3A-3C. Gene expression in different tissues. FIG. 3A. Fold reduction or induction of unique transcripts for each of the comparisons analyzed. The source of the transcripts included in each comparison are displayed in FIG. 3C. The relative expression of each transcript was determined by dividing the number of transcript tags in each comparison in the order displayed in FIG. 3C. To avoid division by 0, we used a tag value of 1 for any tag that was not detectable in one of the samples. We then rounded these ratios to the nearest integer; their distribution is plotted on the X axis. The number of transcripts displaying each ratio is plotted on the Y axis. Each comparison is represented by a specific color (see below or FIG. 3C). FIG. 3B. Expression of transcripts for each comparison, where values on X and Y axes represent the observed transcript tag abundances in each of the two compared sets. Light Blue symbols: DLD1 in different physiologic conditions; Yellow symbols: DLD1 cells (X axis) versus HCT116 cells (Y axis); Red symbols: colon cancer cells (X axis) versus normal brain (Y axis); and Dark Blue symbols: colon cancer cells (X axis) versus hemangiopericytoma (Y axis). FIG. 3C. Fraction of transcripts with dramatically altered expression. For each comparison, Expression Change denotes the number of transcripts induced or reduced 10 fold, and (%) denotes the number of altered transcripts divided by the number of unique transcripts in each case. Differences between expression changes were evaluated using the chi squared test, where the expected expression changes were assumed to be the average expression change for any two comparisons.

TABLE LEGENDS

[0054] Table 1. Table of tissues and transcript tags analyzed. “Tissues” represents the source of the RNA analyzed, “Libraries” indicates the number of SAGE libraries analyzed, “Total Transcripts” is the total number of transcripts analyzed from each tissue, and “Unique Transcripts” denotes the number of unique transcripts observed in each tissue.

[0055] Table 2. Table of transcript abundance. “Copies/cell” denotes the category of expression level analyzed in transcript copies per cell, “Unique Transcripts” represents the number of unique transcripts observed and those matching GenBank genes or ESTs, and “Mass fraction mRNA” represents the fraction of mRNA molecules contained in each expression category.

[0056] Table 3. Table showing tissue-specific transcripts. The number in parentheses adjacent to the tissue type indicates the percent of transcripts exclusively expressed in a given tissue at 10 copies per cell. “Transcript tag” denotes the 10 bp tag adjacent to 4 bp NlaIII anchoring enzyme site, “Copies/cell” denotes the transcript copies per cell expressed, and “UniGene Description” provides a functional description of each matching UniGene cluster (from UniGene Build No. 67). As UniGene cluster numbers change over time, the most recent cluster assignment for each tag can be obtained individually at the Uniform Resource Locator (URL) address for the http file type found on the www host server that has a domain name of ncbi.nlm.gov, a path to the SAGE directory, and file name of SAGEtag.cgi (Lal et al., “A public database for gene expression in human cancers,” Cancer Research, in press) or for the entire table at the URL address: http file type, www host server, domain name sagenet.org, transcriptome directory.

[0057] Table 4. Table showing ubiquitously expressed genes. “Copies/cell” denotes the average expression level of each transcript from all tissues examined, “Range” represents the range in expression for each transcript tag among all tissues analyzed in copies per cell, and “Range/Avg” is the ratio of the range to the average expression level and provides a measure of uniformity of expression. Other table columns are the same as in Table 5. The entire table of uniformly expressed transcripts also is available at the URL address: http file type, www host server, domain name sagenet.org, transcriptome directory.

[0058] Table 5. Table showing transcripts uniformly elevated in human cancers. Transcripts expressed at 3 copies/cell whose expression is at least 2-fold higher in each cancer compared to its corresponding normal tissue. CC, colon cancer; BC, brain cancer; BrC, breast cancer; LC, lung cancer; M, melanoma; NC, normal colon epithelium; NB, normal brain; NBr, normal breast epithelium; NL, normal lung epithelium; NM, normal melanocytes. “Avg T/N” is the average ratio of expression in tumor tissue divided by normal tissue (for the purpose of obtaining this ratio, expression values of 0 are converted to 0.5). Other table columns are the same as in Table 5.

[0059] Table 6. Table showing transcripts expressed in colon cancer cells at a level of at least 500 copies per cell.

[0060] Table 7. Table showing transcripts expressed at a level of at least 500 copies per cell.

DETAILED DESCRIPTION OF THE INVENTION

[0061] It is a discovery of the present invention that particular sets of expressed genes (“transcriptomes”) are expressed only in cancer cells; expression of these genes can be used, inter alia, to identify a test cell as cancerous and to screen for anticancer drugs. These cancer-specific genes can also provide targets for therapeutic intervention.

[0062] It is another discovery of the invention that other transcriptomes are differentially associated with distinct cell types; expression of genes of these transcriptomes can therefore be used to identify a test cell as belonging to one of these distinct cell types.

[0063] It is yet another discovery of the invention that genes of another transcriptome are expressed ubiquitously; expression of genes of this transcriptome can be used to standardize expression of other genes in a variety of gene expression assays.

[0064] To identify the transcriptomes described herein we used the SAGE method, as described in Velculescu et al. (1) and Velculescu et al. (12), to analyze gene expression in a variety of different human cell and tissue types. The SAGE method is also described in U.S. Pat. Nos. 5,866,330 and 5,695,937. A total of 84 SAGE libraries were generated from 19 tissues (Table 1). Diseased tissues included cancers of the colon, pancreas, breast, lung, and brain, as well as melanoma, hemangiopericytoma, and polycystic kidney disease. Normal tissues included epithelia of the colon, breast, lung, and kidney, melanocytes, chondrocytes, monocytes, cardiomyocytes, keratinocytes, and cells of prostate and brain white matter and astrocytes.

[0065] A total of 3,496,829 transcript tags were analyzed and found to represent 134,135 unique transcripts after correcting for sequencing errors (transcript data available at the URL address: http file type, www host server, domain name sagenet.org, transcriptome directory). Expression levels for these transcripts ranged from 0.3 to a high of 9,417 transcript copies per cell in lung epithelium. Comparison against the GenBank and UniGene collections of characterized genes and expressed sequence tags (ESTs) revealed that 6,900 transcript tags matched known genes, while 65,735 matched ESTs. The remaining 61,500 transcript tags (46%) had no matches to existing databases and corresponded to previously uncharacterized or partially sequenced transcripts.

[0066] Each of the genes or transcripts whose expression can be measured in the methods of the invention comprises a unique sequence of at least 10 contiguous nucleotides (the “SAGE tag”). Genes which are differentially expressed in colon, lung, kidney, and breast epithelial cells, brain cells, prostate cells, keratinocytes, or melanocytes are shown in Table 3. Ubiquitously expressed genes are shown in Table 4. Transcripts which are expressed only in cancer tissues, e.g., colon cancer, breast cancer, brain cancer, liver cancer, and melanoma, are shown in Table 5.

[0067] This information provides heretofore unavailable picture of human transcriptomes. These results, like the human genome sequence, provide basic information integral to future experimentation in normal and disease states. Because SAGE analyses provide absolute expression levels, future SAGE data can be directly integrated with those described here to provide progressively deeper insights into gene expression patterns. Eventually, a relatively complete description of the transcripts expressed in diverse cell types and in various physiologic states can be obtained.

[0068] Isolated Polynucleotides

[0069] The invention provides isolated polynucleotides comprising either deoxyribonucleotides or ribonucleotides. Isolated DNA polynucleotides according to the invention contain less than a whole chromosome and can be either genomic DNA or DNA which lacks introns, such as cDNA. Isolated DNA polynucleotides can comprise a gene or a coding sequence of a gene comprising a sequence as shown in SEQ ID NOS:1-1563, such as polynucleotides which comprise a sequence selected from the group consisting of SEQ ID NOS:2, 5, 6, 8, 10, 12, 13, 15, 17, 18, 21, 24-26, 28, 30, 31, 34-36, 38, 40, 47-51, 53-57, 59-62, 65-69, 71-76, 78, 80-84, 98, 103, 113, 115, 122, 129, 132, 134, 135, 140, 144, 149, 150, 153-168, 174-176, 182, 185, 186, 188, 190, 200, 201, 205-213, 216-224, 237, 239, 257, 263, 485, 487, 495, 499, 514, 586, 686, 751, 835, 844, 878, 910, 925, 932, 951, 1000, 1005, 1070, 1122, 1130, 1170, 1173, 1187, 1189, 1200, 1213, 1220, 1237, 1257, 1264, 1273, 1293, 1300, 1320, 1367, 1371, 1401, 1403, 1404, 1406, 1418, and 1419.

[0070] Any technique for obtaining a polynucleotide can be used to obtain isolated polynucleotides of the invention. Preferably the polynucleotides are isolated free of other cellular components such as membrane components, proteins, and lipids. They can be made by a cell and isolated, or synthesized using an amplification technique, such as PCR, or by using an automatic synthesizer. Methods for purifying and isolating polynucleotides are routine and are known in the art.

[0071] Isolated polynucleotides also include oligonucleotide probes, which comprise at least one of the sequences shown in SEQ ID NOS:1-1563. An oligonucleotide probe is preferably at least 10, 11, 12, 13, 14, 15, 20, 30, 40, or 50 or more nucleotides in length. If desired, a single oligonucleotide probe can comprise 2, 3, 4, or 5 or more of the sequences shown in SEQ ID NOS:1-1563. The probes may or may not be labeled. They may be used, for example, as primers for amplification reactions, such as PCR, in Southern or Northern blots, or for in situ hybridization.

[0072] Oligonucleotide probes of the invention can be made by expressing cDNA molecules comprising one or more of the sequences shown in SEQ ID NOS:1-1563 in an expression vector in an appropriate host cell. Alternatively, oligonucleotide probes can be synthesized chemically, for example using an automated oligonucleotide synthesizer, as is known in the art.

[0073] Solid Supports Comprising Polynucleotides

[0074] Polynucleotides, particularly oligonucleotide probes, preferably are immobilized on a solid support. A solid support can be any surface to which a polynucleotide can be attached. Suitable solid supports include, but are not limited to, glass or plastic slides, tissue culture plates, microtiter wells, tubes, gene “chips,” or particles such as beads, including but not limited to latex, polystyrene, or glass beads. Any method known in the art can be used to attach a polynucleotide to a solid support, including use of covalent and non-covalent linkages, passive absorption, or pairs of binding moieties attached respectively to the polynucleotide and the solid support.

[0075] Polynucleotides are preferably present on an array so that multiple polynucleotides can be simultaneously tested for hybridization to polynucleotides present in a single biological sample. The polynucleotides can be spotted onto the array or synthesized in situ on the array. Such methods include older technologies, such as “dot blot” and “slot blot” hybridization (53, 54), as well as newer “microarray” technologies (55-58). A single array contains at least one polynucleotide, but can contain more than 100, 500, 1,000, 10,000, or 100,000 or more different probes in discrete locations.

[0076] Determining Expression of a Gene Product

[0077] Each of the methods of the invention involves measuring expression of a gene product of at least one of the genes identified in Tables 3, 4, and 5 (SEQ ID NOS:1-1448). If desired, expression of gene products of at least 2, 3, 4, 5, 6, 7, 8, 9, 10, 15, 20, 25, 30, 50, 75, 100, 125, 250, 500, 1,000, 1,250, or more genes can be determined.

[0078] Either protein or RNA products of the disclosed genes can be determined. Either qualitative or quantitative methods can be used. The presence of protein products of the disclosed genes can be determined, for example, using a variety of techniques known to the art, including immunochemical methods such as radioimmunoassay, Western blotting, and immunohistochemistry. Alternatively, protein synthesis can be determined in vivo, in a cell culture, or in an in vitro translation system by detecting incorporation of labeled amino acids into protein products.

[0079] RNA expression can be determined, for example, using at least 1, 2, 3, 4, 5, 10, 15, 20, 25, 30, 50, 75, 100, 125, 250, 500, 1,000, 5,000, 10,000, or 100,000 or more oligonucleotide probes, either in solution or immobilized on a solid support, as described above. Expression of the disclosed genes is preferably determined using an array of oligonucleotide probes immobilized on a solid support. In situ hybridization can also be used to detect RNA expression.

[0080] Identification of Cell Types

[0081] Cell-type specific genes are expressed at a level greater than 10 copies per cell in a particular cell type, such as epithelial cells of the colon, breast, lung, and kidney, keratinocytes, melanocytes, and cells from the prostate and brain, but are not expressed in cells of other tissues. Such cell-type specific genes represent “cell-type specific transcriptomes.” The fraction of cell-type-specific transcripts ranges from 0.05% in normal prostate to 1.76% in normal colon epithelium. Approximately 50% of these transcripts tags match known genes or ESTs. The vast majority of these cell-type-specific genes have not been previously reported in the literature to be cell-type specific.

[0082] Cell type-specific genes are shown in Table 3. Genes which comprise the sequences shown in SEQ ID NOS:1-85 are uniquely expressed in colon epithelial cells. Genes which comprise the sequences shown in SEQ ID NOS:86-151 are uniquely expressed in brain cells. Genes which comprise the sequences shown in SEQ ID NOS:152-155 are uniquely expressed in keratinocytes. Genes which comprise the sequences shown in SEQ ID NOS:156-160 are uniquely expressed in breast epithelial cells. Genes which comprises the sequences shown in SEQ ID NOS:161-167 are uniquely expressed in lung epithelial cells. Genes which comprises the sequences shown in SEQ ID NOS:168-208 are uniquely expressed in melanocytes. Genes which comprise the sequences shown in SEQ ID NOS:209 and 210 are uniquely expressed in prostate cells. Genes which comprise the sequences shown in SEQ ID NOS:211-225 are uniquely expressed in kidney epithelial cells. Thus, determination of expression of at least one gene from each of these uniquely expressed groups, particularly those not previously known to be uniquely expressed, can be used to identify a test cell as an epithelial cell of the colon, breast, lung, and kidney, a keratinocyte, a melanocyte, or a cell from the prostate or brain.

[0083] Test cells can be obtained, for example, from biopsy or surgical samples, forensic samples, cell lines, or primary cell cultures. Test cells include normal as well as cancer cells, such as primary or metastatic cancer cells.

[0084] To identify a test cell as an epithelial cell of the colon, breast, lung, and kidney, a keratinocyte, a melanocyte, or a cell from the prostate or brain, expression of a gene product of at least one gene is determined, using methods such as those described above. If a test cell expresses a gene comprising a sequence shown in SEQ ID NOS:2, 5-18, and 20-85, the test cell is identified as a colon epithelial cell. If a test cell expresses a gene comprising a sequence shown in SEQ ID NOS:87-96, 98, 100-103, 105, 107-110, 112-129, and 131-151, the test cell is identified as a brain cell. If a test cell expresses a gene comprising a sequence shown in SEQ ID NOS:152-155, the test cell is identified as a keratinocyte. If a test cell expresses a gene comprising a sequence shown in SEQ ID NOS:156-160, the test cell is identified as a breast epithelial cell. If a test cell expresses a gene comprising a sequence shown in SEQ ID NOS:161-167, the test cell is identified as a lung epithelial cell. Expression of a gene comprising a sequence shown in SEQ ID NOS:168, 170, 172-177, 179-188, and 190-208 identifies the test cell as a melanocyte. Expression of a gene comprising a sequence shown in SEQ ID NOS:209 and 210 identifies the test cell as a prostate cell. Expression of a gene which comprises a sequence shown in SEQ ID NOS:211-225 identifies the test cell as a kidney epithelial cell.

[0085] Identifying a Test Cell as a Cancer Cell

[0086] A cancer-specific gene is expressed at a level of at least 3 copies per cancer cell, such as a colon cancer, breast cancer, brain cancer, lung cancer, or melanoma cell, at a level which is at least two-fold higher than expression of the same gene in a corresponding normal cell. Cancer-specific genes which comprise the sequences shown in SEQ ID NOS:226-265 (Table 5) represent a “cancer transcriptome.” SEQ ID NOS:237, 239, 257, and 263 are sequences which are found in transcripts of novel cancer-specific genes of the invention. Oligonucleotide probes corresponding to cancer-specific genes can be used, for example, to detect and/or measure expression of cancer-specific genes for diagnostic purposes, to assess efficacy of various treatment regimens, and to screen for potential anti-cancer drugs.

[0087] For example, determination of the expression level of any of these genes in a test cell relative to the expression level of the same gene in a normal cell (a cell which is known not to be a cancer cell) can be used to determine whether the test cell is a cancer cell or a non-cancer cell.

[0088] Test cells can be any human cell suspected of being a cancer cell, including but not limited to a colon epithelial cell, a breast epithelial cell, a lung epithelial cell, a kidney epithelial cell, a melanocyte, a prostate cell, and a brain cell. Test cells can be obtained, for example, from biopsy samples, surgically excised tissues, forensic samples, cell lines, or primary cell cultures. Comparison can be made to a non-cancer cell type, including to the corresponding non-cancer cell type, either at the time expression is measured in the test cell or by reference to a previously determined expression standard.

[0089] To identify a test cell as a cancer cell, expression of a gene product of at least one gene is determined, using methods such as those described above. The at least one gene comprises a sequence selected from the group consisting of SEQ ID NOS:226-265, particularly from the group consisting of SEQ ID NOS:228, 230-236, 238, 240-256, 258-260, and 262-265. An increase in expression of the at least one gene in the test cell which is at least two-fold more than the expression of the at least one gene in a cell which is not cancerous identifies the test cell as a cancer cell.

[0090] Reducing Cancer-Specific Gene Expression

[0091] Cancer-specific genes provide potential therapeutic targets for treating cancer or for use in model systems, for example, to screen for agents which will enhance the effect of a particular compound on a potential therapeutic target. Thus, a reagent can be administered to a human cell, either in vitro or in vivo, to reduce expression of a cancer-specific gene. The reagent specifically binds to an expression product of a gene comprising a sequence selected from the group consisting of SEQ ID NOS:226-265, particularly from the group consisting of SEQ ID NOS:228, 230-236, 238, 240-256, 258-260, and 262-265.

[0092] If the expression product is a protein, the reagent is preferably an antibody. Protein products of cancer-specific genes can be used as immunogens to generate antibodies, such as a polyclonal, monoclonal, or single-chain antibodies, as is known in the art. Protein products of cancer-specific genes can be isolated from primary or metastatic tumors, such as primary colon adenocarcinomas, lung cancers, astrocytomas, glioblastomas, breast cancers, and melanomas. Alternatively, protein products can be prepared from cancer cell lines such as SW480, HCT116, DLD1, HT29, RKO, 21-PT, MDA-468, A549, and the like. If desired, cancer-specific gene coding sequences can be expressed in a host cell or in an in vitro translation system. An antibody which specifically binds to a protein product of a cancer-specific gene provides a detection signal at least 5-, 10-, or 2-fold higher than a detection signal provided with other proteins when used in an immunochemical assay. Preferably, the antibody does not detect other proteins in immunochemical assays and can immunoprecipitate the cancer-specific protein product from solution.

[0093] For administration in vitro, an antibody can be added to a tissue culture preparation, either as a component of the medium or in addition to the medium.

[0094] In another embodiment, antibodies are delivered to specific tissues in vivo using receptor-mediated targeted delivery. Receptor-mediated DNA delivery techniques are taught in, for example, Findeis et al. Trends in Biotechnol. 11, 202-05, (1993); Chiou et al., GENE THERAPEUTICS: METHODS AND APPLICATIONS OF DIRECT GENE TRANSFER (J. A. Wolff, ed.) (1994); Wu & Wu, J. Biol. Chem. 263, 621-24, 1988; Wu et al., J. Biol. Chem. 269, 542-46, 1994; Zenke et al., Proc. Natl. Acad. Sci. U.S.A. 87, 3655-59, 1990; Wu et al., J. Biol. Chem. 266, 338-42, 1991.

[0095] If single-chain antibodies are used, polynucleotides encoding the antibodies can be constructed and introduced into cells using well-established techniques including, but not limited to, transferrin-polycation-mediated DNA transfer, transfection with naked or encapsulated nucleic acids, liposome-mediated cellular fusion, intracellular transportation of DNA-coated latex beads, protoplast fusion, viral infection, electroporation, “gene gun,” and DEAE- or calcium phosphate-mediated transfection.

[0096] Effective in vivo dosages of an antibody are in the range of about 5 μg to about 50 μg/kg, about 50 μg to about 5 mg/kg, about 100 μg to about 500 μg/kg of patient body weight, and about 200 to about 250 μg/kg of patient body weight. For administration of polynucleotides encoding single-chain antibodies, effective in vivo dosages are in the range of about 100 ng to about 200 ng, 500 ng to about 50 mg, about 1 μg to about 2 mg, about 5 μg to about 500 μg, and about 20 μg to about 100 μg of DNA.

[0097] If the expression product is mRNA, the reagent is preferably an antisense oligonucleotide. The nucleotide sequence of an antisense oligonucleotide is complementary to at least a portion of the sequence of the cancer-specific gene. Preferably, the antisense oligonucleotide sequence is at least 10 nucleotides in length, but can be at least 11, 12, 15, 20, 25, 30, 35, 40, 45, or 50 or more nucleotides long. Longer sequences also can be used. An antisense oligonucleotide which specifically binds to an mRNA product of a cancer-specific gene preferably hybridizes with no more than 3 or 2 mismatches, preferably with no more than 1 mismatch, even more preferably with no mismatches.

[0098] Antisense oligonucleotides can be deoxyribonucleotides, ribonucleotides, or a combination of both. Oligonucleotides, including modified oligonucleotides, can be prepared by methods well known in the art (47-52) and introduced into human cells using techniques such as those described above. The cells can be in a primary culture of human tumor cells, in a human tumor cell line, or can be primary or metastatic tumor cells present in a human body.

[0099] Preferably, a reagent reduces expression of a cancer-specific gene by at least 10%, 20%, 30%, 40%, 50%, 60%, 70%, or 80% relative to expression of the gene in the absence of the reagent. Most preferably, the level of gene expression is decreased by at least 90%, 95%, 99%, or 100%. The effectiveness of the mechanism chosen to decrease the level of expression of a cancer-specific gene can be assessed using methods well known in the art, such as hybridization of nucleotide probes to cancer-specific gene mRNA, quantitative RT-PCR, or immunologic detection of a protein product of the cancer-specific gene.

[0100] Screening for Anti-Cancer Drugs

[0101] According to the invention, test compounds can be screened for potential use as anti-cancer drugs by assessing their ability to suppress or decrease the expression of at least one cancer-specific gene. The cancer-specific gene comprises a sequence selected from the group consisting of SEQ ID NOS:226-265, particularly from the group consisting of SEQ ID NOS:228, 230-236, 238, 240-256, 258-260, and 262-265. Test compounds can be pharmacologic agents already known in the art or can be compounds previously unknown to have any pharmacological activity, including small molecules from compound libraries. Test substances can be naturally occurring or designed in the laboratory. They can be isolated from microorganisms, animals, or plants, or can be produced recombinantly or synthesized by chemical methods known in the art.

[0102] To screen a test compound for use as a possible anti-cancer drug, a cancer cell is contacted with the test compound. The cancer cell can be a cell of a primary or metastatic tumor, such as a tumor of the colon, breast, lung, prostate, brain, or kidney, or a melanoma, which is isolated from a patient. Alternatively, a cancer cell line, such as colon cancer cell lines HCT116, DLD1, HT29, Caco2, SW837, SW480, and RKO, breast cancer cell lines 21-PT, 21-MT, MDA-468, SK-BR3, and BT-474, the A549 lung cancer cell line, and the H392 glioblastoma cell line, can be used.

[0103] Expression of a gene product of at least one gene is determined using methods such as those described above. The gene comprises a sequence selected from the group consisting of SEQ ID NOS:226-265, preferably from the group consisting of SEQ ID NOS:228, 230-236, 238, 240-256, 258-260, and 262-265, even more preferably from the group consisting of SEQ ID NOS:237, 239, 257, and 263. A decrease in expression of the gene in the cancer cell identifies the test compound as a potential anti-cancer drug.

[0104] Standardizing Expression of a Test Gene

[0105] Genes which comprise the sequences shown in SEQ ID NOS:266-1448 (Table 4) are expressed at a level of at least five transcript copies per cell in every cell type analyzed, including epithelia of the colon, breast, lung, and kidney, melanocytes, chondrocytes, monocytes, cardiomyocytes, keratinocytes, prostate cells, and astrocytes, oligodendrocytes, and other cells present in the white matter of brain. These genes thus represent members of the “minimal transcriptome,” the set of genes expressed in all human cells. The minimal transcriptome includes well known genes which are often used as experimental controls to normalize gene expression, such as glyceraldehyde 3-phosphate dehydrogenase, elongation factor 1 alpha, and gamma actin.

[0106] Ubiquitously expressed genes can be used to compare expression of a test gene in a test sample to expression of a gene in a standard sample. A ubiquitously expressed gene preferably comprises a sequence shown in SEQ ID NOS:266-375, 377-652, 654-796, and 798-1448, and more preferably comprises a sequence shown in SEQ ID NOS:282, 288, 300, 302, 308, 320, 323, 363, 368, 379, 381, 444, 453, 518, 531, 535, 538, 542, 579, 580, 594, 600, 604, 617, 626, 641, 650, 717, 728, 776, 777, 794, 818, 822, 842, 885, 887, 899, 900, 902, 904, 914, 930, 960, 964, 1001, 1015, 1020, 1027, 1035, 1090, 1113, 1119, 1146, 1151, 1163, 1233, 1235, 1252, 1255, 1270, 1340, 1345, 1356, 1359, 1360, 1362, 1385, 1415, and 1441.

[0107] Two ratios are determined using gene expression assays such as those described above. The first ratio is an amount of an expression product of a test gene in a test sample to an amount of an expression product of at least one ubiquitously expressed gene comprising a sequence selected from the group consisting of SEQ ID NOS:266-375, 377-652, 798-1447, and 1448 in the test sample. The second ratio is an amount of an expression product of the test gene in a standard sample to an amount of an expression product of the ubiquitously expressed gene in the standard sample. Expression of either the test gene or the ubiquitously expressed gene can be used as the denominator. If desired, multiple ratios can be determined, such as (a) an amount of an expression product of more than one test gene to that of a single ubiquitously expressed gene, (b) an amount of an expression product of a single test gene to that of more than one ubiquitously expressed genes, or (c) an amount of an expression product of more than one test gene to that of more than one ubiquitously expressed gene. Optionally, the ratio in the standard sample can be predetermined.

[0108] The ratios determined in the test and standard samples are compared. A different between the ratios indicates a difference in the amount of the expression product of the test gene in the test sample.

[0109] The standard and test samples can be matched samples, such as whole cell cultures or homogenates of cells (such as a biopsy sample) and differ only in that the test biological sample has been subjected to a different environmental condition, such as a test compound, a drug whose effect is known or unknown, or altered temperature or other environmental condition. Alternatively, the test and standard samples can be corresponding cell types which differ according to developmental age. In one embodiment, the test sample is a cancer cell, such as a colon cancer, breast cancer, lung cancer, melanoma, or brain cancer cell, and the standard sample is a normal cell.

[0110] The test gene can be a gene which encodes a protein whose biological function is known or unknown. Preferably the ratio of expression between the test gene sample. Even more preferably, expression of the ubiquitously expressed gene is not altered in the test sample. A difference between the first ratio of expression in the test sample and a second ratio of expression in the standard sample can therefore be used to indicate a difference in expression of the test gene in the test sample.

[0111] Screening for Compounds for Increasing an Organ or Cell Function

[0112] Test compounds can be screened for the ability to increase an organ or cell function by assessing their ability to increase expression of at least one tissue-specific gene. The tissue-specific gene comprises a sequence selected from at least one of the following groups:

[0113] (a) the sequences shown in SEQ ID NOS:2, 5-18, 20-84, and 85;

[0114] (b) the sequences shown in SEQ ID NOS:87-96, 98, 100-103, 105, 107-110, 112-129, 131-150, and 151;

[0115] (c) the sequences shown in SEQ ID NOS:152-154, and 155;

[0116] (d) the sequences shown in SEQ ID NOS:156-159 and 160;

[0117] (e) the sequences shown in SEQ ID NOS:161-166 and 167;

[0118] (f) the sequences shown in SEQ ID NOS:168, 170, 172-177, 179-188, 190-207, and 208;

[0119] (g) the sequences shown in SEQ ID NOS:209 and 210; and

[0120] (h) the sequences shown in SEQ ID NOS:211-224 and 225.

[0121] As with the anti-cancer drug screening method described above, test compounds can be pharmacologic agents already known in the art or can be compounds previously unknown to have any pharmacological activity, including small molecules from compound libraries. Test substances can be naturally occurring or designed in the laboratory. They can be isolated from microorganisms, animals, or plants, or can be produced recombinantly or synthesized by chemical methods known in the art.

[0122] To screen a test compound for the ability to increase an organ or cell function, a cell, such as a colon epithelial cell, a brain cell, a keratinocyte, a breast epithelial cell, a lung epithelial cell, a melanocyte, a prostate cell, or a kidney cell, is contacted with the test compound. The cell can be a primary culture, such as an explant culture, of tissue obtained from a human, or can originate from an established cell line.

[0123] Expression of a gene product of at least one gene is determined using methods such as those described above. An increase in expression of a gene product of at least one gene comprising a sequence selected from (a) identifies the test compound as a potential drug for increasing a function of a colon cell. An increase in expression of a gene product of at least one gene comprising a sequence selected from (b) identifies the test compound as a potential drug for increasing a function of a brain cell. An increase in expression of a gene product of at least one gene comprising a sequence selected from (c) identifies the test compound as a potential drug for increasing a function of a skin cell. An increase in expression of a gene product of at least one gene comprising a sequence selected from (d) identifies the test compound as a potential drug for increasing a function of a breast cell. An increase in expression of a gene product of at least one gene comprising a sequence selected from (e) identifies the test compound as a potential drug for increasing a function of a lung cell. An increase in expression of a gene product of at least one gene comprising a sequence selected from (f) identifies the test compound as a potential drug for increasing a function of a melanocyte. An increase in expression of a gene product of at least one gene comprising a sequence selected from (g) identifies the test compound as a potential drug for increasing a function of a prostate cell. An increase in expression of a gene product of at least one gene comprising a sequence selected from (h) identifies the test compound as a potential drug for increasing a function of a kidney cell.

[0124] Restoring Function to a Diseased Tissue or Cell

[0125] Function can be restored to a diseased tissue or cell, such as a melanocyte or a colon, brain, keratinocyte, breast, lung, prostate, or kidney cell, by delivering an appropriate tissue-specific gene to cells of that tissue. The tissue specific gene comprises a nucleotide sequence selected from at least one of the following groups:

[0126] (a) the sequences shown in SEQ ID NOS:2, 5-18, 20-84, and 85 (colon-specific);

[0127] (b) the sequences shown in SEQ ID NOS:87-96, 98, 100-103, 105, 107-110, 112-129, 131-150, and 151 (brain-specific);

[0128] (c) the sequences shown in SEQ ID NOS:152-154, and 155 (keratinocyte-specific);

[0129] (d) the sequences shown in SEQ ID NOS:156-159 and 160 (breast-specific);

[0130] (e) the sequences shown in SEQ ID NOS:161-166 and 167 (lung-specific);

[0131] (f) the sequences shown in SEQ ID NOS:168, 170, 172-177, 179-188, 190-207, and 208 (melanocyte-specific);

[0132] (g) the sequences shown in SEQ ID NOS:209 and 210 (prostate-specific); and

[0133] (h) the sequences shown in SEQ ID NOS:211-224 and 225 (kidney-specific).

[0134] Expression of the gene in a cell of the diseased tissue preferably is 10, 20, 30, 40, 50, 60, 70, 80, or 90% less than expression of the gene in a cell of the corresponding tissue which is normal. In some cases, the diseased cell fails to express the gene. A tissue-specific gene which is administered to cells for this purpose includes a polynucleotide comprising a coding sequence which is intron-free, such as a cDNA, as well as a polynucleotide which comprises elements in addition to the coding sequence, such as regulatory elements.

[0135] Coding sequences of many of the tissue-specific genes disclosed herein are publicly available. For the novel tissue-specific genes identified here, coding sequences can be obtained using a variety of methods, such as restriction-site PCR (Sarkar, PCR Methods Applic. 2:318-322, 1993), inverse PCR (Triglia et al., Nucleic Acids Res. 16:8186, 1988), capture PCR (Lagerstrom, et al., PCR Methods Applic. 1:111-119, 1991). Alternatively, the partial sequences disclosed herein can be nick-translated or end-labeled with ³²P using polynucleotide kinase using labeling methods known to those with skill in the art (BASIC METHODS IN MOLECULAR BIOLOGY, Davis et al., eds., Elsevier Press, N.Y., 1986). A lambda library prepared from the appropriate human tissue can then be directly screened with the labeled sequences of interest.

[0136] Many methods for introducing polynucleotides into cells or tissues are available and can be used to deliver a tissue-specific gene to a cell in vitro or in vivo. Introduction of the tissue-specific gene into a cell can be accomplished by any method by which a nucleic acid molecule can be inserted into a cell, such as transfection, electroporation, microinjection, lipofection, adsorption, and protoplast fusion. For in vitro administration, a tissue-specific gene can be added to a tissue culture preparation, either as a component of the medium or in addition to the medium. In vivo administration can be by means of direct injection of a vector comprising a tissue-specific gene to the particular tissue or cells to which the tissue-specific gene is to be delivered. Alternatively, the tissue-specific gene can be included in a vector which is capable of targeting a particular tissue and administered systemically (59-61).

[0137] For in vitro administration, suitable concentrations of a tissue-specific gene in the culture medium range from at least about 10 pg to 100 pg/ml, about 100 pg to about 500 pg/ml, about 500 pg to about 1 ng/ml, about 1 ng to about 10 ng/ml, about 10 ng to about 100 ng/ml, or about 100 ng/ml to about 500 ng/ml. For local administration, effective dosages of a tissue-specific gene range from at least about 10 ng to about 100 ng, about 50 ng to 150 ng, about 100 ng to about 250 ng, about 1 μg to about 10 μg, about 5 μg to about 50 μg, about 25 μg to about 100 μg, about 75 μg to about 250 μg, about 100 μg to about 250 μg, about 200 μg to about 500 μg, about 500 μg to about 1 mg, about 1 mg to about 10 mg, about 5 mg to about 50 mg, about 25 mg to about 100 mg, or about 50 mg to about 200 mg of DNA per injection. Suitable concentrations for systemic administration range from at least about 500 ng to about 50 mg, about 1 μg to about 2 mg, about 5 μg to about 500 μg, and about 20 μg to about 100 μg of DNA per kg of body weight.

[0138] Recombinant DNA technologies can be used to improve expression of the tissue-specific gene by manipulating, for example, the number of copies of the gene in the cell, the efficiency with which the gene is transcribed, the efficiency with which the resultant transcripts are translated, and the efficiency of post-translational modifications. Recombinant techniques useful for increasing the expression of a tissue-specific gene in a cell include, but are not limited to, providing the tissue-specific gene in a high-copy number plasmid, integrating the tissue-specific gene into one or more host cell chromosomes, adding vector stability sequences to plasmids, substituting or modifying transcription control signals (e.g., promoters, operators, enhancers), substituting or modulating translational control signals (e.g., ribosome binding sites, Shine-Dalgarno sequences), and deleting sequences that destabilize transcripts. (See Dow et al., U.S. Pat. No. 5,935,568).

[0139] Preferably, delivery of the tissue-specific gene increases expression of a gene product of the tissue-specific gene in the cell or tissue by at least 10, 20, 30, 40, 50, 60 70, 80, 90, 95, 98, 99, or 100% relative to expression of the tissue-specific gene in a diseased cell or tissue to which the gene has not been delivered. Expression of a protein product of the tissue-specific gene can be determined immunologically, using methods such as radioimmunoassay, Western blotting, and immunohistochemistry. Alternatively, incorporation of labeled amino acids into a protein product can be determined. RNA expression is preferably determined using one or more oligonucleotide probes, either in solution or immobilized on a solid support, as described above.

[0140] All documents cited in this disclosure are expressly incorporated herein. The above disclosure generally describes the present invention, and all references cited in this disclosure are incorporated by reference herein. A more complete understanding can be obtained by reference to the following specific examples which are provided for purposes of illustration only and are not intended to limit the scope of the invention.

EXAMPLE 1

[0141] Tissue Samples and the SAGE Method

[0142] RNA for normal tissues was obtained from the following sources: colon epithelial cells isolated from sections of normal colon mucosa from two patients (41); HaCaT keratinocyte cells (42), normal mammary epithelial cells from two individuals (Clonetics); normal bronchial epithelial cell from two individuals (43); normal melanocytes from two individuals (Cascade Biologics); normal cultured monocytes, dendritic cells and TNF activated dendritic cells; two normal kidney epithelial cell lines; cultured chondrocyte cells from two normal individuals and one patient with osteoarthritic disease; normal fetal cardiomyocytes in normoxic and hypoxic conditions; and normal brain white matter from two patients and normal cultured astrocyte cells.

[0143] RNA for diseased tissues was obtained from the following sources: primary colon adenocarcinomas from two patients, HCT116, DLD1, HT29, Caco2, SW837, SW480, and RKO colon cancer cell lines cultured in vitro in a variety of different cellular conditions including log phase growth, G1/G2 phase growth arrest, and apoptosis (40, 41, 44, 45); primary pancreatic adenocarcinomas from two patients and ASPC-1 and PL-45 pancreatic cancer cell lines (41); breast cancer cell lines 21-PT, 21-MT, MDA-468, SK-BR3, and BT-474; primary lung squamous cell cancers from two patients (43), primary lung adenocarcinoma from one patient, and the A549 lung cancer cell line (43); primary melanomas from 3 patients; kidney epithelial cells lines from two patients with polycystic kidney disease; hemangiopericytomas from 5 patients; primary glioblastoma tumors from two patients; and the H392 glioblastoma cell line.

[0144] Isolation of polyadenylate RNA and the SAGE method for all tissues was performed as previously described (1, 12; see also U.S. Pat. Nos. 5,866,330 and 5,695,937).

EXAMPLE 2

[0145] Data Analysis

[0146] The SAGE software (12) was used to analyze raw sequence data and to identify a total of 3,668,175 SAGE tags. Of these, 171,346 tags (4.7%) corresponded to linker sequences and were removed from further analysis. The remaining 3,496,829 tags were derived from transcript sequences, but a small fraction of these contained sequencing errors. SAGE analysis of yeast (1), for which the entire genome sequence is known, demonstrated a sequencing error rate of ˜0.7% per bp, translating to a tag error rate of 6.8% (1-0.993; 10), in accord with sequence errors measured in the current data set.

[0147] To provide as accurate an estimate of unique genes as possible, we accounted for sequencing errors in two ways. First, we only considered tags that occurred twice in the data set. Although this requirement might have removed legitimate transcript tags expressed at very low levels (less than approximately 0.2 copies per cell, or 2 copies in 3,496,829 transcript tags), it eliminated the majority of sequencing errors (172,276 tags).

[0148] Second, because of the size of the data set utilized, it was possible that the same sequencing error in a given tag may be observed multiple times. To account for these, tags with expression levels high enough to give multiple redundant errors were analyzed for single base substitutions, insertions, and deletions. If the observed expression level of a tag did not exceed its expected incidence due to redundant errors by a factor of five, it was assumed to be the result of a repeated sequencing error. This identified and removed an additional 27,051 unique tags (156,174 total tags), a number very similar to estimates of multiple sequencing errors obtained by Monte Carlo simulations.

[0149] In total, these corrections amount to a sequencing error rate of approximately 9.4%, suggesting that our analyses more than fully accounted for sequencing errors and that the remaining 134,135 unique transcript tags represented a conservative accounting of legitimate transcripts.

[0150] Transcript tags were matched to known genes and ESTs by use of tables containing matching 10 bp transcript sequences, UniGene clusters, GenBank accession numbers, and functional descriptions downloaded from the SAGEmap web site (URL address: http file type, www server, domain name ncbi.nlm.nih.gov, SAGE directory) (Lal et al., in press) on Feb. 23, 1999 (UniGene build 70, at the URL address: http file type, www server, domain name ncbi.nlm.nih.gov, UniGene directory) and the Microsoft Access software.

[0151] As UniGene clusters numbers may change over time, the most recent tag to cluster mapping can be obtained for each transcript tag individually at the URL address: http file type, www host server, domain name ncbi.nlm.nih.gov, SAGE directory, file name SAGEtag.cgi, or for the entire data set at the URL address: http file type, www host server, domain name sagenet.org, transcriptome directory. A total of 37,534 distinct transcripts from the UniGene database contained polyadenylation signals or polyadenylated tails and matched the collection of SAGE transcript tags; these corresponded to 23,534 unique UniGene clusters.

[0152] Transcript abundance per cell was determined simply by dividing the observed number of tags for a given transcript by the total number of transcripts obtained. An estimate of about 300,000 transcripts per cell was used to convert the abundances to copies per cell (46). For tissue specific transcripts, only transcript tags expressed at nominally ≧10 transcript copies per cell were considered in order to normalize for tissues with fewer total tags analyzed.

[0153] The following transcript data from this analysis are available electronically at the SAGEnet website (that has a URL address: http file type, www host server, domain name sagenet.org, transcriptome directory) with the corresponding expression levels and UniGene descriptions: 134,135 unique transcript tags identified from 3.5 million total transcripts tags; 69,381 transcript tags identified from colon cancer cells; 217 transcripts that are exclusively expressed in colon epithelium, keratinocytes, breast epithelium, lung epithelium, melanocytes, kidney epithelium and cells from prostate and brain; 987 transcripts that were expressed in all tissues. Individual transcript libraries from a total of ˜800,000 transcript tags from colon epithelium, normal brain, colon cancer, and brain cancer are available at the SAGEmap website (at the URL address: http file type, www host server, domain name ncbi.nlm.nih.gov, SAGE directory) (Lal et al., in press).

EXAMPLE 3

[0154] Estimation of the Number of Genes Present in the Human Genome

[0155] The transcripts detected by SAGE provides an estimate of the number of genes present in the human genome. Historically, estimates of the number of unique genes in the genome have ranged from 60,000 to over 100,000 genes using analyses of EST clustering (15), frequency of genes in characterized genomic regions, frequency of CpG islands (16), and RNA-cDNA reassociation kinetics (4). If one were to assume that each unique transcript tag observed by SAGE corresponded to a unique gene, our data would indicate that there are approximately 134,000 genes in the human genome.

[0156] However, such an approach is likely to overestimate the number of unique genes in the genome, as distinct transcripts can be derived from a single gene. Multiple sites for polyadenylation (17), alternative splicing, premature transcriptional termination (18), as well as polymorphisms in the SAGE tag or nearby restriction endonuclease site could lead to multiple transcript tags for any one gene. An analysis of all publicly available 3′ end-derived ESTs revealed that this was the case for many transcripts, and provided an estimate of the multiplicity of transcripts expected for individual genes. 37,534 distinct 3′ transcripts containing polyadenylation signals or polyadenylated tails were observed to correspond to 23,534 unique UniGene clusters, an average 1.6 different transcripts per gene. Applying a similar calculation to our SAGE data would suggest that the 134,135 transcripts observed corresponded to 84,103 unique genes. As our SAGE data is by no means a complete analysis of transcripts from all possible tissues, this estimate would provide a lower boundary for the number of unique genes in the genome. This figure is significantly higher than the 65,538 genes estimated from a clustering of 982,808 ESTs (UniGene Build 70) (15), and suggests that a substantial number of genes expressed at low levels may not be present in current EST databases.

EXAMPLE 4

[0157] Assessment of Transcriptome Complexity

[0158] Assessment of transcriptome complexity requires a relatively complete sampling of a transcriptome for the cell type under analysis. Human cells are thought to contain close to 300,000 mRNA molecules, and therefore an analysis of at least several hundred thousand transcripts would be needed. Approximately 350,000 and 300,000 transcripts were analyzed from DLD1 and HCT116 colorectal cancer cells, respectively. As these cancer cells are diploid, have similar genetic and phenotypic properties, and have very similar gene expression patterns (see below), transcript tags obtained from these cells were analyzed in combination as well as individually

[0159] Analysis of either cell line afforded approximately a one fold coverage of the 300,000 mRNA molecules in a cell, while the combined set represented a two fold coverage even for mRNA molecules present at a single copy per cell. Measurement of ascertained new tags at increasing increments of tags indicated that the fraction of new transcripts from analysis of additional tags approached 0 at approximately 650,000 tags in the combined set (FIG. 1). This suggested that generation of further SAGE tags would yield few additional genes, and Monte Carlo simulations indicated that analysis of 643,283 tags would identify at least one tag for a given transcript 96% of the time if its expression level was at least two transcript copies per cell, and 83% of the time if its expression level was at least one transcript copy per cell.

[0160] The combined 643,283 transcript tags represented 69,381 unique transcripts, of which 44,174 corresponded to known genes or ESTs in the GenBank or UniGene databases while 25,207 represented previously undescribed transcripts (Table 2). Even when accounting for multiple unique transcripts per gene, these transcripts would represent at least 43,502 unique genes. This is substantially higher than the previous estimate of 15,000-25,000 expressed genes obtained by RNA-DNA reassociation kinetics in a variety of human cell types (4), and suggests that a significant fraction of the genome may be expressed in individual cell types. As the kinetics of reassociation of a particular class of RNA and cDNA may be affected by a number of experimental variables and may underestimate transcripts of low abundance (4), it is not surprising that our studies have detected a higher number of expressed genes than estimated by hybridization analysis in both human cells (Table 2) and yeast.

EXAMPLE 5

[0161] Expression Levels of Transcripts in Colon Cancer Cells

[0162] Expression levels of transcripts in the colon cancer cell ranged from 0.5 to 2341 copies per cell. The 61 transcripts expressed at over 500 transcript copies per cell made up nearly 1/4 of the mRNA mass of the cell and the most highly expressed 623 genes accounted for % of the mRNA content. In contrast, the vast majority of unique transcripts were expressed at low levels, with just under 23% of the mRNA mass of the cell comprising 90% of the unique transcripts expressed (Table 2). A “virtual rot” analysis of the expressed transcripts identified a relatively continuous distribution of gene expression without markedly discrete abundance classes, similar to those observed in previous rot studies of human cancer cells (20) (FIG. 2).

[0163] The identities of the expressed genes reveal the diversity of expression of a human transcriptome (data available at the URL address: http file type, www host server, domain name sagenet.org, transcriptome directory). For example, highly expressed genes often encoded proteins important in protein synthesis, energy metabolism, cellular structure and certain tissue specific functions. Moderate and low abundance genes accounted for a multitude of cellular processes including protein modification enzymes, DNA replication machinery, cell surface receptors, components of signal transduction pathways and transcription factors as well as many other transcripts with currently unknown functions.

EXAMPLE 6

[0164] Differences in Gene Expression Between Different Tissues

[0165] Differences in gene expression between different tissues may provide insights into the specialized processes underlying human physiology in normal and diseased states. In line with previous observations, overall gene expression patterns among the 19 different tissues analyzed were similar (examples in FIGS. 3A-3C). Changes in gene expression between physiologic states of a particular cell type or between patient samples of the same tissue were less than changes between cell types of different origins (FIGS. 3A-3C). Likewise, only a small fraction of transcripts was exclusively expressed in a particular normal or disease tissue. Detailed analysis of transcripts from epithelia of colon, breast, lung, and kidney, melanocytes, and cells from prostate and brain, identified transcripts that were nominally expressed at greater than 10 copies per cell in one tissue but not in any other tissue studied. The fraction of these tissue-specific transcripts ranged from 0.05% in normal prostate to 1.76% in normal colon epithelium (Table 3). Approximately 50% of these transcript tags matched known genes or ESTs (examples in Table 3 and data available at the URL address: http file type, www host server, domain name sagenet.org, transcriptome directory). Some of these transcripts identified genes already reported to be important for tissue specific processes. For example, brain specific transcripts such as GABA receptor, myelin basic protein, and synaptopodin are known to be important for synaptic transmission (21) formation and maintenance of the myelin sheath (22) and dendrite shape and motility (23), respectively. Likewise, guanylin/uroguanylin (24), carbonic anhydrase 1 (25), and CDX2 (26) are known to be expressed in colonic epithelium. 5,6-dihydroxyindole-2-carboxylic acid oxidase has been shown to have an important role for normal melanocyte pigment synthesis (27), while expression of MART-1 and melastatin may have clinical implications for melanoma patients (28, 29). However, the vast majority of the tissue specific transcripts observed have not been previously reported in the literature and their roles in the tissue examined remain to be elucidated.

EXAMPLE 7

[0166] Minimal Transcriptome

[0167] Nearly 1000 transcripts were detected that were expressed at 5 transcript copies per cell in every cell type analyzed. These expressed genes represent a view into the “minimal transcriptome,” the set of genes expressed in all human cells. Such genes, listed in order of their uniformity of expression in Table 4 (and available at the URL address: http file type, www host server, domain name sagenet.org, transcriptome directory), largely represent well known constitutive or housekeeping genes thought to provide the molecular machinery necessary for basic functions of cellular life (4). Genes involved in DNA, RNA, protein, lipid and oligosaccharide biosynthesis as well as in energy metabolism were among those observed. Additionally, genes from other functional classes including structural proteins (e.g., dystroglycan and myosin light chain), signaling molecules (e.g., 14-3-3 proteins and MAPKK2), proteins with compartmentalized functions (e.g., lysosome-associated membrane glycoprotein and ER lumen retaining protein receptor 1), cell surface receptors (e.g., FGF receptor and STRL22 G protein coupled receptor), proteins involved in intracellular transport (e.g., syntaxin and alpha SNAP), membrane transporters (e.g., Na+/K+ ATPase and mitochondrial F1/F0 ATPase), and enzymes involved in post-translational modification and protein degradation (e.g., kinases, phosphatases and proteasome components) were observed and were not previously known to be ubiquitously expressed. Well known genes often used as experimental controls such as glyceraldehyde 3-phosphate dehydrogenase, elongation factor 1 alpha, and gamma actin were observed but varied in expression as much as 6 fold among different cell types.

EXAMPLE 8

[0168] Genes Involved in Tumorigenesis

[0169] Genes that are uniformly expressed in cancers but expressed at lower levels in normal tissues may turn out to be important for tumorigenesis, and demonstrate how gene expression patterns might be useful in the analysis of disease states. We detected 40 genes that were expressed in all cancer tissues examined at levels 3 transcript copies per cell and whose expression was at least 2-fold higher in each cancer compared to its corresponding normal tissue (Table 5). Four of these transcripts had no matches to known genes and 15 matched ESTs with no known function. Several of the highly induced transcripts provided tantalizing clues about their roles in tumorigenesis. For example, S100A4 has been thought to play a role in late stage tumorigenesis as it is overexpressed in colorectal adenocarcinomas but not adenomas (30), and its induction can promote (while its inhibition can prevent) metastasis in tumor models. Midkine, a heparin-binding growth factor has been reported to be overexpressed in certain cancers (34), to transform cells in vitro (35), and to promote tumor angiogenesis in vivo. Finally, overexpression of survivin, an IAP apoptosis inhibitor (37) has been recently shown to predict shorter survival rates in colorectal cancer patients and may carry out its antiapoptotic functions as a mitotic spindle checkpoint factor (39). The observed elevated expression of such genes in many tumor types indicates a potentially general role for these genes in tumorigenesis and suggests they may be useful as diagnostic markers or targets for therapeutic intervention.

EXAMPLE 9

[0170] Estimate of Gene Number

[0171] The 134,135 distinct transcripts identified in this study, corresponding to approximately 84,103 unique genes, provided an estimate of gene number substantially higher than the recent estimate (˜65,000 genes) derived from extant EST clusters. What could account for the difference between these estimates, considering that both are derived from sequencing of transcripts from similar cell types? One explanation is that the clustering estimate is based on the number of observed EST clusters (62,236) divided by a measure of the completeness of the EST database. The latter value is calculated as the fraction of “characterized” genes in GenBank that already have EST matches (˜95%). The characterized genes in GenBank have been assumed to be representative of the rest of the genes in the human genome, but our SAGE data indicated that their average expression was more than 10 fold higher than the mean levels of gene expression. Similarly, the number of ESTs that were present in clusters with characterized genes was approximately 12 fold higher than clusters composed entirely of ESTs. Such highly expressed genes would be more likely to be represented in transcript databases, thereby leading to an overestimation of the completeness of the EST databases, and an underestimation of the number of unique genes. Indeed, the number of UniGene clusters continues to grow as a greater diversity of tissues is analyzed through the Cancer Genome Anatomy Project, and as of the date of submission of this manuscript already exceeds the recent EST derived estimate (71,849 gene clusters in Build 80 versus 65,538 predicted from Build 70).

[0172] Like other genome-wide analyses, studies of human transcriptomes using SAGE have several potential limitations. First, a small number of transcripts would be expected to lack the restriction enzyme site required to produce the 14 bp tags, and would therefore not be detected by our analyses (12). Second, our study was limited to the 19 tissues analyzed. Genes uniquely expressed in other tissues would not have been detected, and accordingly, genes observed to be tissue specific in our studies may turn out to be expressed in other normal or disease states. Finally, identification of genes corresponding to specific tags is mainly based on large but incomplete databases of ESTs and characterized genes. SAGE tags without matches to existing databases can directly be used to identify previously uncharacterized genes (1, 12, 40), but additional 3′ EST data, as well as that of genomic regions would make gene identification more rapid.

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[0233] 61. Lai & Lien, Exp. Nephrol. 7, 11-14 (1999) TABLE 1 Tissues and transcript tags analyzed Libraries Total Transcripts Unique Genes Normal tissues Colon epithelium^(1, 2) 2 98,089 12,941 Keratinocytes³ 2 83,835 12,598 Breast epithelium³ 2 107,632 13,429 Lung epithelium⁴ 2 111,848 11,636 Melanocytes³ 2 110,631 14,824 Prostate³ 2 98,010 9,786 Monocytes³ 3 66,673 9,504 Kidney epithelium³ 2 103,836 15,094 Chondrocytes³ 4 88,875 11,628 Cardiomyocytes³ 4 77,374 9,449 Brain² 3 202,448 23,580 Diseased Tissues Colon cancer^(1, 2, 3) 22 1,004,509 56,153 Pancreatic cancer¹ 4 126,414 17,050 Breast cancer³ 5 226,630 18,685 Lung cancer⁴ 5 221,302 22,783 Melanoma³ 10 269,332 25,600 Polycystic kidney 2 112,839 16,280 dise

Hemangiopericytoma³ 5 199,985 31,351 Brain cancer² 3 186,567 23,108 Total 84 3,496,829 84,103

[0234] TABLE 2 Transcript abundance Colon Cancer Cells Unique Mass fraction Copies/Cell transcripts mRNA (%) >500 61 20 Match GenBank (%) 61 (100) 50 to 500 562 27 Match GenBank (%) 554 (99) 5 to 50 6,358 30 Match GenBank (%) 6,023 (95) <=5 62,400 23 Match GenBank (%) 37,536 (60) Total 69,381 100 Match GenBank (%) 44,174 (64)

[0235] TABLE 3 Tissue-specific genes SEQ ID Copies/ Tag sequence NO: Observed cell Unigene Description Colon epithelium (1.76%) ATACTCCACT 1 141 431 Guanylate cyclase activator 2 (guanylin, intestinal, heat-stable) TCAGCTGCCA 2 72 220 No match GTCATCACCA 3 57 174 H. sapiens mRNA for GCAP-II/uroguanylin precursor CCTTCAAATC 4 46 141 Carbonic anhydrase I ACACCCATCA 5 29 89 No match CCAACACCAG 6 28 86 No match AATAGTTTCC 7 23 79 Pregnancy-specific beta-1 glycoprotein 6 CCAGGCGTCA 8 18 55 No match GAACAGCTCA 9 18 55 ESTs TACTCGGCCA 10 15 46 No match GGGGGAGAAG 11 12 37 ESTs AGTGGGCTCA 12 11 34 No match GAGCACCGTG 13 11 34 No match GATCTATCCA 14 10 31 ESTs GAACGCCAGA 15 9 28 No match GCCCTCGGAG 16 9 28 ESTs ACAAGCCTAG 17 9 28 No match GTCACAGGAA 18 9 28 No match GCCCTCGGAG 19 9 28 Human homeobox protein Cdx2 mRNA, complete cds CTAGGATGAT 20 9 28 ESTs CCAACTATCG 21 8 24 No match CTGACGGGGA 22 8 24 ESTs GAGGGTTTTA 23 8 24 Homo sapiens C19-steroid specific UDP-glucronosyltransferase mRNA, complete cds GGGGTCCCAT 24 8 24 No match GCCAGGTCAC 25 7 21 No match AGAACACCAA 26 7 21 No match AATCCCGCCC 27 7 21 Homo sapiens hAQP8 mRNA for aquaporin 8, complete cds ACACTGCCTC 28 6 18 No match AGAGTCCAGG 29 6 18 Homo sapiens carcinoembryonic antigen (CGM2) mRNA, complete cds CCAGACGTAG 30 6 18 No match GAGGCCCCCG 31 6 18 No match CTGTGTGCCC 32 5 15 ESTs, Weaky similar to tryptase-III [H. sapiens] GAGAGGATGG 33 5 15 ESTs GGCTGAACCA 34 5 15 No match CCAAATCATT 35 5 15 No match ACGGCTGGGC 36 5 15 No match ACCTTCATCT 37 5 15 EST AGGGCTTGAG 38 5 15 No match ACCTTCATCT 39 5 15 Human rearranged metabotropic glutamate receptor type II (GLUR2) mRNA, complete cds TCAGGCCAGA 40 5 15 No match CTGTGTGCCC 41 5 15 ESTs GGATGTCAAC 42 5 15 Human RecA-like protein (hREC2) mRNA, complete cds ATCTGGAGCA 43 5 15 Alcohol dehydrogenase 1 (class I), alpha polypeptide GAGAGGATGG 44 5 15 INTEGRAL MEMBRANE PROTEIN E16 ATCTGGAGCA 45 5 15 Alcohol dehydrogenase 3 (class I), gamma polypeptide GGATGTCAAC 46 5 15 Polymeric immunoglobulin receptor CACAGACACA 47 4 12 No match TGCTCCTAAC 48 4 12 No match TATACCCGGA 49 4 12 No match TATCCTGATG 50 4 12 No match GGCCCTCCCG 51 4 12 No match GTAGCGATGG 52 4 12 Pim-1 oncogene GCAGGTTGTG 53 4 12 No match TGGGAACCGG 54 3 9 No match ACACCTCTCT 55 3 9 No match GGAAAACAGG 56 3 9 No match CAGGCGGCAC 57 3 9 No match CAGGTTGGTC 58 3 9 Homo sapiens hRVP1 mRNA for RVP1, complete cds GGGATATAAA 59 3 9 No match GTGGAAAATC 60 3 9 No match GTGTGTGAAT 61 3 9 No match ATGTGACACT 62 3 9 No match ATGGTGTAAT 63 3 9 ESTs TCACATTGAT 64 3 9 H. sapiens mRNA for Ll-cadherin TAACTAAACA 65 3 9 No match TGCCCGGGTC 66 3 9 No match TAGTCGGAAA 67 3 9 No match GCTATACGGG 68 3 9 No match TCACACCCCA 69 3 9 No match CTGCCCGAAC 70 3 9 ESTs AGTCACCTCT 71 3 9 No match TCATTGGTTT 72 3 9 No match TCCTCTCCTC 73 3 9 No match CCTCTCGGCC 74 3 9 No match CCACTGAAGT 75 3 9 No match CTGGCTTGCT 76 3 9 No match GAAAACAGAA 77 3 9 EST AAAGCACGTC 78 3 9 No match GAAAACAGAA 79 3 9 ESTs, Weakly similar to synapse-associated protein sap47-1 [D. melanogaster] TTGATTCCAT 80 3 9 No match AAACAGGCAC 81 3 9 No match CTTACAGTCC 82 3 9 No match GAATGGACTC 83 3 9 No match GAACCCAAAC 84 3 9 No match GAAAACAGAA 85 3 9 ESTs ACTTTGTCCC 86 160 237 Glial fibrillary acidic protein GTGCGAATCC 87 79 117 ESTs CAAAAAGTTA 88 36 53 ESTs TTAACTTTAT 89 33 49 Homo sapiens neuroendecrine-specific protein A (NSP) mRNA, complete cds CAGCCAAATG 90 29 43 ESTs GCCTGTGGTG 91 28 41 Homo sapiens LY6H mRNA, complete cds CTTAGGGACA 92 26 39 ESTs TTGGAGGTGA 93 22 33 ESTs ATTCCATTTC 94 20 30 ESTs ATTCCATTTC 95 20 30 ESTs, Highly similar to RAS-RELATED PROTEIN RAB-10 [Canis familiaris] AGAGAGCGGA 96 19 28 Human guanine nucleotide-binding regulatory protein (Go-alpha) gene TTCTCAATAC 97 19 28 Homo sapiens mRNA for synaplopodin CATCCTCCCA 98 19 28 No match GTATCGATTT 99 16 24 Homo sapiens GABA-B receptor mRNA, complete cds TTGTAAACAG 100 15 22 ESTs, Weakly similar to cyclin 1 [H. sapiens] GCCCTGTATT 101 15 22 ESTs CCACATTGCC 102 15 22 Homo sapiens chromosome 7q22 sequence CAGGGCAACG 103 15 22 No match AAAAGCAAAT 104 15 22 Human mRNA for MOBP (myelin-assoclated oligodendrocylic basic protein), complete Cds, clone hOPRP1 ACCAATCCTA 105 14 21 Human guanine nucleotide-binding regulatory protein (Go-alpha) gene CTGTGTGTCC 106 13 19 AXONIN-1 PRECURSOR TCAGACAATA 107 12 18 ESTs TGGTGAGATG 108 12 18 ESTs ATTTTTTGTT 109 12 18 ESTs ACATTGAGTC 110 12 18 Homo sapiens mRNA for MEGF4, partial cds GTCAGTCTAC 111 11 16 Glutamate receptor, metabotropic 3 GTCCCACTTC 112 11 16 ESTs GGGGCCCGAA 113 11 16 No match TGACTCACCC 114 10 15 Homo sapiens calmodulin-stimulated phosphodiesterase PDE1B1 mRNA, complete cds GACAGCGACA 115 10 15 No match GGTGTACATA 116 10 15 No match TAGCTATAAA 117 10 15 ESTs GGTGTACATA 118 10 15 ESTs GTTTCATTTT 119 10 15 ESTs AATAAATTGC 120 10 15 ESTs GTTTCATTTT 121 10 15 ESTs ACACATTGTA 122 10 15 No match TACCTATTGT 123 10 15 ESTs TTTAGCAGAA 124 10 15 Homo sapiens cyclin E2 mRNA, complete cds TTTAGCAGAA 125 10 15 ESTs CAATTTATGA 126 9 13 ESTs GTGAAGGTTT 127 9 13 Homo sapiens (huc) mRNA, complete cds TGGACTTTTA 128 9 13 ESTs CGATGCCACG 129 9 13 No match GTGAAGGTTT 130 9 13 Neuron-specific RNA recognition motifs (RRMs)-containing protein [human, hippocampus, mRNA, 1992nt] TGGACTTTTA 131 9 13 ESTs CCTTCTTGTC 132 9 13 No match TCCATTCAAG 133 9 13 Human clone 23586 mRNA sequence CCTATGTATC 134 8 12 No match ACGGACCAAT 135 8 12 No match TATTATCTTG 136 8 12 ESTs ACTTTATACG 137 8 12 ESTs ACTTTATACG 138 8 12 ESTs, Weakly similar to EPIDERMAL GROWTH FACTOR RECEPTOR KINASE SUBSTRATE EPS8 [H. sapiens] CGCAGTCCCC 139 8 12 BETA-NEOENDORPHIN-DYNORPHIN PRECURSOR TGTAGTGCTC 140 8 12 No match CTGCTTAAGT 141 8 12 ESTs, Weakly similar to unknown [H. sapiens] ACAAGTGGAA 142 8 12 Human mRNA for KIAA0027 gene, partial cds AATCCCAATG 143 7 10 Homo sapiens mRNA for KIAA0283 gene, partial cds ACTATGCATC 144 7 10 No match ACGAGTCATT 145 7 10 ESTS TTACATTGTA 146 7 10 Homo sapiens clone 24461 mRNA sequence ATGCCCCCTC 147 7 10 ESTs, Highly similar to HYPOTHETICAL 52.2 KD PROTEIN ZK512.6 IN CHROMOSOME III [Caenorhabditis elegans] TTTTATTCAT 148 7 10 ESTs ACAGAGCATT 149 7 10 No match TGACCAATAG 150 7 10 No match AATCCCAATG 151 7 10 Plastin 1 (I isoform) Keratinacytes (0.087%) GCGAACTGGG 152 5 18 ORPHAN RECEPTOR TR4 GCAACACTAA 153 3 11 No match GTAATGGATT 154 3 11 No match AGCAGACGTG 155 3 11 No match Breast Epithelium (0.14%) GGATTCGGTC 156 6 17 No match CGGAAGGCGG 157 5 14 No match TGTAAGTACG 158 5 14 No match GATCAGTCAT 159 4 11 No match GCTCAGAGTT 160 4 11 No match Lung epithelium (0.17%) TAACCTCCCC 161 90 241 No match AGGAACAACT 162 6 16 No match GGGTCCGTGG 163 6 16 No match TAGCAAAATA 164 5 13 No match GCTGTGCACA 165 4 11 No match CAGAAAATCA 166 4 11 No match GATTTGCTGG 167 4 11 No match Melanocyte (0.93%) GTGCCATTCT 168 114 309 No match GATATTTGTC 169 40 108 5,6-DIHYDROXYINDOLE-2-CARBOXYLIC ACID OXIDASE PRECURSOR TATGATTTTA 170 39 106 ESTs TCACTGCAAC 171 27 73 5,6-DIHYDROXYINDOLE-2-CARBOXYLIC ACID OXIDASE PRECURSOR CCCAGTCACA 172 21 57 ESTs, Weakly similar to LACTOSE PERMEASE [Escherichia coli] TATGAGAACC 173 17 46 ESTs, Highly similar to HIGH AFFIMMUNOGLOBULIN GAMMAFC RECEPTOR I PRECURSOR [Homo sapiens] GAGTTTAGTG 174 16 43 No match CTCCACTCTG 175 15 41 No match ATCCAGTGAC 176 14 38 No match TGATCTTGAG 177 14 38 ESTs Moderately similar to PAS protein 5 [H. sapiens] AATGGCTGTT 178 12 33 Human melanoma antigen recognized by T-cells (MART-1) mRNA ATACTAAAAA 179 12 33 Human cysteine protease CPP32 isofarm alpha mRNA, complete cds ATACTAAAAA 180 12 33 EST GTTTATTAAA 181 10 27 PROTEIN-TYROSINE PHOSPHATASE ZETA PRECURSOR AGAAATCAGT 182 9 24 No match TTGGATATTA 183 9 24 Homo sapiens clone 23785 mRNA sequence AATTGAGTAG 184 9 24 Human DNA sequence from PAC 257A7 on chromosome 6p24. Contains two unknown genes and ESTs, STSs and a GSS TGAGTGCTGC 185 9 24 No match GCAGTACAGT 186 8 22 No match GAATTCAGGA 187 7 19 Homo sapiens mRNA for KIAA0679 protein, partial cds GACTTCTTTA 188 7 19 No match GAATTCAGGA 189 7 19 Homo sapiens melastatin 1 (MLSN1) mRNA, complete cds GTTTATACTG 190 7 19 No match GAATTCAGGA 191 7 19 Homo sapiens mRNA for synaptosome associated protein of 23 kilodaltons, isoform A GCCCGTGTAG 192 6 16 Msh (Drosophila) homeo box hamolog 1 (formerly homeo box 7) TGGGGTGTGC 193 6 16 Homo sapiens thyroid receptor interector (TRIP8) mRNA, 3 end of cds AATTTTTATG 194 5 14 Interferon regulatory factor 4 TCAGTGTCTG 195 5 14 ESTs GGAGGTCAGC 196 5 14 ESTs TTCTTCTCAA 197 5 14 ESTs TTCTTCTCAA 198 5 14 ESTs GGTTGTCTCT 199 5 14 ESTs, Weakly similar to line-1 protein ORF2 [H. sapiens] CTTTGTTTAC 200 5 14 No match CACTATAGAA 201 5 14 No match TTTGGTTACA 202 4 11 EST TCAAAACAAT 203 4 11 Human R kappa B mRNA, complete cds TTTGGTTACA 204 4 11 Homo sapiens clone 23688 mRNA sequence TATAGAGCAA 205 4 11 No match TAATAACCAG 206 4 11 No match TTCTATACTG 207 4 11 No match GGAATACGGC 208 4 11 No match Prostate (0.05%) TGAACTGGCA 209 3 9 No match AATGTTGGGG 210 3 9 No match Normal Kidney (0.27%) CGACAAACTA 211 4 12 No match GTAGCACAGA 212 4 12 No match ACCGTCAATC 213 4 12 No match TGGATCAGTC 214 4 12 Human mRNA for KIAA0259 gene, partial cds TGGCTCGGTC 215 4 12 EST GCGACTGCGA 216 4 12 No match GCACTAGCTG 217 3 9 No match GCGGCCGGTT 218 3 9 No match CGGCAGTCCC 219 3 9 No match GCCCACCTGT 220 3 9 No match CGGCGGATGG 221 3 9 No match CCCCAGGCCG 222 3 9 No match CCCATTCCAA 223 3 9 No match TCAAGAGGTG 224 3 9 No match ATAACTGTTG 225 3 9 Human HFREP-1 mRNA for unknown protein, complete cds

[0236] TABLE 4 Ubiquitously expressed transcripts Tag SEQ ID Copies/ Range/ sequence NO: cell Range Avg Unigene Description CATCTAAACT 266 44 22-62 0.91 Human mRNA for KIAA0038 gene, partial cds GGGCAAGCCA 267 27 14-40 1.00 STEROID HORMONE RECEPTOR ERR1 ATTCAGCACC 268 29 11-40 1.03 ESTs, Highly similar to signal peptidase: SUBUNIT = 12kD TTGTTATTGC 269 15  6-21 1.04 Annexin VII (synexin) ACAGGGTGAC 270 115  47-165 1.04 Homo sapiens mRNA for EDF-1 protein GCTTCCATCT 271 39 17-58 1.06 H. sapiens BAT1 mRNA for nuclear RNA helicase (DEAD family) GCTTCCATCT 272 39 17-58 1.06 BB1 = malignant cell expression-enhanced gene/tumor progression-enhanced gene GAGGGTGGCG 273 21  9-32 1.08 Human DR-nm23 mRNA, complete cds GCAGGGTGGG 274 34 15-53 1.10 V-akt murine thymoma viral oncogene homolog 2 AGCCCTCCCT 275 85  42-136 112 Homo sapiens autoantigen p542 mRNA, complete cds ATGGCCATAG 276 15  5-22 112 Human mRNA for YSK1, complete cds GTGGGTGTCC 277 20  9-32 1.13 ESTs TGTAGTTTGA 278 41 14-62 1.14 Transcription elongation factor B (SIII), polypeptlde 1-like GGGGCTGTGG 279 14  6-21 1.15 Human TFIIIC Box B-binding subunit mRNA, complete cds GGGGCTGTGG 280 14  6-21 1.15 Homo sapiens mRNA for smallest subunit of ubiquinol-cytochrome c reductase, complete cds CACGCAATGC 281 111  53-182 1.17 Human homolog of Drosophila enhancer of split m9/m10 mRNA, complete cds CTCACACATT 282 49 20-78 1.18 LYSOSOME-ASSOCIATED MEMBRANE GLYCOPROTEIN 1 PRECURSOR CAAATGAGGA 283 36 15-58 1.19 Neuroblastoma RAS viral (v-ras) oncogene homolog TGTAAGTCTG 284 21  8-33 1.19 Human p62 mRNA, complete cds ACCAAGGAGG 285 83  25-100 1.19 ESTs ACCAAGGAGG 286 63  25-100 1.19 DNA-DIRECTED RNA POLYMERASE II 23 KD POLYPEPTIDE ACCAAGGAGG 287 63  25-100 1.19 Human mRNA for transcription elongation factor S-II, hS-II-T1, complete cds TGAGGCAGGG 288 17  7-27 1.20 Syntaxin 5A TCCACGCACC 289 39 14-61 1.20 ESTs TAGGGCAATC 290 40 14-62 1.21 H. sapiens rnRNA for SMT3B protein GGTAGCCTGG 291 61 25-98 1.21 Damage-specific DNA binding protein 1 (127 kD) TCAACAGCCA 292 14  8-23 1.21 Human translation initiation factor 3 47 kDa subunit mRNA, complete cds CTCTGTGTGG 293 18  7-29 1.21 Homo sapiens EB1 mRNA, complete cds CCTATTTACT 294 115  51-193 1.23 Cytochrome coxidase subunit IV TGCATCTGGT 295 104  32-162 1.24 78 KD GLUCOSE REGULATED PROTEIN PRECURSOR GCTCTCTATG 296 72  21-111 1.25 H. sapiens mRNA for rat translocon-associated protein delta homolog GAAGGCATCC 297 39 18-64 1.25 PROBABLE 26S PROTEASE SUBUNIT TBP-1 CCACTCCTCA 298 59 19-93 1.26 DEFENDER AGAINST CELL DEATH 1 GCTGTCATCA 299 31  8-47 1.27 26S PROTEASE REGULATORY SUBUNIT 4 CGGCTGGTGA 300 63  24-105 1.28 Proteasom component C5 AAGCCAGGAC 301 65  26-110 1.31 Homo sapiens chromosome 19, cosmid R32469 TGAGAGGGTG 302 32 15-57 1.32 14-3-3 PROTEIN TAU GCGTGATCCT 303 33 10-54 1.32 ALCOHOL DEHYDROGENASE CTGCCAACTT 304 51 11-78 1.33 COFILIN, NON-MUSCLE ISOFORM CCAAACGTGT 305 148  56-254 1.33 HISTONE H3.3 GCGGGAGGGC 306 45 12-72 1.34 ADP-RIBOSYLATION FACTOR-LIKE PROTEIN 2 GGCCAGCCCT 307 70  20-114 1.34 ESTs GGCCAGCCCT 308 70  20-114 1.34 Phosphofructokinase (liver type) TGGGCAAAGC 309 608  189-1014 1.36 Translation elongation factor 1 gamma GCAAAACCAG 310 29 12-52 1.36 Human mRNA for KIAA0002 gene, complete cds ACTTACCTGC 311 107  33-179 1.36 ytochrome c oxidase subunit VIb GTTGGTCTGT 312 32 11-54 136 ESTs TGCTACTGGT 313 18  7-32 136 Surfeit 1 GACGACACGA 314 401  71-618 1.37 Rbosomal protein S28 CAAGTGGCAA 315 18  5-31 1.37 Homo sapiens Grf4O adaptor protein (Grf40) mRNA, complete cds TACTCTTGGC 316 72  16-114 1.37 HETEROGENEOUS NUCLEAR RIBONUCLEOPROTEIN L GACTGTGCCA 317 75  15-118 1.37 Human cytoplasm light chain 1 hdlc1) mRNA, complete cds TTGCCGGTTA 318 19  9-34 1.37 Homo sapiens clone 24592 mRNA sequence CATTGCAGGA 319 14  5-25 1.38 Homo sapiens Chromosome 16 BAC clone CIT9897SK-A-152E5 CAGGAACGGG 320 97  26-159 1.38 DUAL SPECIFICITY MITOGEN-ACTIVATED PROTEIN KINASE KINASE 2 AATAGGTCCA 321 219  64-371 1.40 Ribosomal protein S25 ACCTCAGGAA 322 67  32-126 1.41 Human high density lipoprotein binding protein (HBP) mRNA, complete cds ATGACTCAAG 323 26 12-48 1.41 Human mRNA for protein tyrosine phosphatase (PTP-BAS, type 2), complete cds ATGACTCAAG 324 26 12-48 1.41 Homo sapiens mRNA, chromosome 1 specific transcript KIAA0488 GCCTCTGCCA 325 26 12-48 1.41 Human mRNA for KIAA0272 gene, partial cds TGCTTGTCCC 326 62  25-112 1.42 ADP-ribosylation factor 1 GGTGGCACTC 327 112  41-199 1.42 Aplysia ras-related homolog 12 GGGCTGGGGT 328 659  168-1102 1.42 H. sapiens mRNA for ribosomal protein L29 GGGCTGGGGT 329 659  168-1102 1.42 Homo sapiens sperm acrosomal protein mRNA, complete cds CACAAACGGT 330 844  252-1449 1.42 40S RIBOSOMAL PROTEIN S27 CATTGAAGGG 331 37 13-66 1.42 Homo sapiens clone 24433 myelodysplasia/Myeloid leukemia factor 2 mRNA, complete cds GTGACTGCCA 332 38 15-69 1.42 DPH2L = candidate tumor suppressor gene {ovarian cancer critical region of deletion} GTGACTGCCA 333 38 15-69 1.42 Homo sapiens clone 24722 unknown mRNA, partial cds AAGACAGTGG 334 678  222-1190 1.43 Ribosomal protein L37a CTGGCTGCAA 335 86  24-147 1.43 Cytochrome c oxidase subunit Vb ACCGGGAGGT 336 18  5-30 1.43 Human DNA from chromosome 19-specific cosmid R27090, genomic sequence ATGGAGACTT 337 26  8-46 1.43 Homo sapiens citrate synthase mRNA, complete cds CAGCTCATCT 338 40 17-74 1.44 Homo sapiens mRNA, complete cds ACGTGGTGAT 339 52  6-81 1.44 ESTs, Highly similar to LEYDIG CELL TUMOR 10 KD PROTEIN [Raltus norvegicus] GCGGTGAGGT 340 37  9-62 1.44 Homo sapiens small glutamine-rich tetratricopeptide repeat (TPR) containing protein GTGGCACACG 341 105  24-176 1.44 Eukaryotic translation initiation factor 3 (elF-3) p36 subunit GTGACAACAC 342 42 11-71 1.45 Voltage-dependentanion channel 1 CTGCTATACG 343 226  70-396 1.45 Ribosomal protein L5 ACTGGCTGCT 344 27 10-50 1.46 ESTs GGAAGCACGG 345 53 15-93 1.46 Human antisecretory factor-1 mRNA, complete cds GGAAGCACGG 346 53 16-93 1.46 Tag matches ribosomal RNA sequence CTGTTGGTGA 347 295  86-516 1.46 40S RIBOSOMAL PROTEIN S23 TCAGATCTTT 348 356 141-663 1.46 Ribosomal protein S4, X-llnked TGGAATGCTG 349 79  37-151 1.46 Homo sapiens NADH: ubiquinone dehydrogenase 51 kDa subunit (NDUFV1) mRNA, nuclear gene encoding mitochondrial protein,complete cds TAAGGAGCTG 350 289  71-493 1.46 RIBOSOMAL PROTEIN s26 GGCTTTGGAG 351 41 15-75 1.46 ESTs CGCACCATTG 352 41 14-74 1.46 GCN5-like 1 = GCN5 homolog/putativeregulator of transcriptional activation {clone GCN5L1} CGCTGGTTCC 353 443 177-825 1.46 Homo sapiens ribosomal protein L11 mRNA, complete cds GGGCCTGGGG 354 62  13-105 1.46 ESTs CTCGAGGAGG 355 43 10-73 1.47 Human ribosomal protein L23-related mRNA, complete cds TTGGTCCTCT 356 1233  383-2177 1.47 60S RIBOSOMAL PROTEIN L41 TCCCTGGCAT 357 15  5-27 1.47 Heterogeneous nuclear ribonucleoprotein K GGGGGCTGCT 358 11  6-23 1.47 ESTs GGGGGCTGCT 359 11  6-23 1.47 Human lysyl oxidase: related protein (WS9-14) mRNA, complete cds CCACCCCGAA 360 109  14-174 1.48 Testis enhanced gene transcript CTGCTAGGAA 361 21  9-40 1.48 H. sapiens mRNA for TRAMP protein AACTGCGGCA 362 15  7-29 1.48 ESTs TGGAGTGGAG 363 134  56-254 1.48 Human guanylate kinase (GUK1) mRNA, complete cds TGAAGGAGCC 364 107  33-191 1.48 ATP SYNTHASE LIPID-BINDING PROTEIN P2 PRECURSOR GGGGACTGAA 365 77  24-136 1.48 Homo sapiens mRNA for low molecular mass ubiquinone-binding protein, complete cds TGCACGTTTT 366 526 196-979 1.49 Human mRNA for antileukoprotease (ALP) from cervix uterus CTGGATGCCG 367 33 11-59 1.49 Radin blood group CCCCCTCGTG 368 24  8-44 1.49 Adrenergic, beta, receptor kinase 1 ATGATGCGGT 369 41 13-74 1.49 Cytoplasmic antiproteinase = 38 kda intracellular serine proteinase inhibitor ATTCTCCAGT 370 356  86-618 1.50 Ribosomal protein L17 CCCCAGTTGC 371 219  90-418 1.50 Calpain small polypeptide CCAAGGATTG 372 21  6-38 1.50 Solute carrier family 5 (sodium/glucose cotransporter), member 2 GACCGAGGTG 373 25  6-43 1.50 Ewing sarcoma breakpoint region 1 GACTCTCTCA 374 13  5-25 1.50 ESTs GACTCTGGGA 375 21  6-37 1.51 ESTs, Moderately similar to T13H5.2 [C. elegans] GACTCTGGGA 376 21  6-37 1.51 Actin, gamma 1 CGCCGCGGTG 377 207  54-368 1.51 Homo sapiens Chromosome 16 SAC clone CIT987SK-A-761H5 CCAGAACAGA 378 361 119-666 1.52 60S RIBOSOMAL PROTEIN L30 CCAGAACAGA 379 361 119-666 1.52 Deoxythymidylate kinase TGGTTTTTGG 380 26  5-43 1.52 Homo sapiens acylprotein thioesterase mRNA, complete cds TTTTTGTACA 381 38 13-71 1.52 ER LUMEN PROTEIN RETAINING RECEPTOR 1 GTTCTCCCAC 382 65  24-122 1.52 ESTs, Highly similar to PROTEIN TRANSPORT PROTEIN SEC61 ALPHA SUBUNIT GACCCTGCCC 383 192  30-323 1.52 Human FK-506 binding protein homologue (FKBP38) mRNA, complete cds GCCCGCCTTG 384 49 16-91 1.52 Homo sapiens (clone mf. 18) RNA polymerase II mRNA, complete cds GGTGCTGGAG 385 24  8-45 1.53 Homo sapiens mRNA for putative methyl transferase TTACCTCCTT 386 78  21-141 1.53 Homo sapiens 3-phosphoglycerate dehydrogenase mRNA, complete cds AAACCAGGGC 387 18  5-33 1.53 ESTs TTCTGGCTGC 388 85  11-141 1.53 Ubiguinol-cytochrome c reductase protein I TTCTGGCTGC 389 85  11-141 1.53 Human BAC clone RG114A06 from 7q31 CTTCTCACCG 390 33  8-58 1.54 Ubiquitin-conjugating enzyme E2l (homologous to yeast UBC9) GAGAACCGTA 391 48 13-87 1.54 ESTs, Moderately similar to regulatoryprotein GCGACCGTCA 392 658   51-1076 1.56 Aldolase A GTCAAGACCA 393 28 11-54 1.56 Adaptin, beta 1 (beta prime) CTGGGTCTCC 394 42 12-76 1.56 60S RIBOSOMAL PROTEIN L13 CGATTCTGGA 395 27 11-53 1.56 H. sapiens mRNA for ras-related GTP-binding protein CAGGAGGAGT 396 73  19-132 1.56 PROBABLE PROTEIN DISULFIDE ISOMERASEER-60 PRECURSOR CAAAATCAGG 397 44 12-81 1.56 Human RNA for cyclin I, complete cds CTGGGTTAAT 398 615  116-1081 1.57 40S RlBOSOMAL PROTEIN S19 TTTTCTGCTG 399 34  8-60 1.57 Hydroxyacyl-Coenzyme A dehydrogenase/3-ketoacyl-Coenzyme A thiolase/enoyl-Coenzyme A hydratase (trifunctional protein), beta subunit CCCTGGCAAT 400 30 14-61 1.57 ESTs AGGCTACGGA 401 807  199-1472 1.58 60S RIBOSOMAL PROTEIN L13A GAGGCCATCC 402 23  8-45 1.58 Homo sapiens chromosome 19, cosmid R30783 CTTTGATGTT 403 26 11-52 1.58 Homo sapiens mRNA for NORI-1, complete cds TTGGACCTGG 404 113  29-208 1.58 ESTs, Weakly similar to MALONYL COA-ACYLCARRIER PROTEIN TRANSACYLASE [E. coli] TTGGACCTGG 405 113  29-206 1.58 ATP synthase, H + transporting, mitochondrial Fl complex, delta subunit GTTCGTGCCA 406 213  43-379 1.58 Ribosomal protein L35a GATGCTGCCA 407 154  34-277 1.58 Human mRNA for Epstein-Barr virus small RNAs (EBERs) associated protein (EAP) ACGGCTCCGA 408 27  8-50 1.58 ESTs GAGTCAGGAG 409 29  6-53 1.59 ESTs, Highly similar to COATOMER ZETA SUBUNIT [Bos taurus] GGAGGCTGAG 410 84  37-171 1.59 Homo sapiens KIAA0792 protein, complete cds GGAGGCTGAG 411 84  37-171 1.59 Homo sapiens putative fatty acid desaturase MLD mRNA, complete cds GTGATGGTGT 412 75  24-143 1.59 Thyroid autoantigen 70kD (Ku antigen) TCAGATGGCG 413 45  6-78 1.59 Homo sapiens hD54 + ins2 isoform (hD54) mRNA, complete cds ATGCGAAAGG 414 32  9-59 1.59 Dodecenoyl-Coenzyme A delta isomerase (3,2 trans-enoyl-Coenzyme A isomerase) TGCTGGGTGG 415 87  26-133 1.60 ESTs, Highly similar to NADH-UBIQUINONE OXIDOREDUCTASE ASHI SUBUNIT PRECURSOR [Bos taurus] TGCTGGGTGG 416 87  26-133 1.60 Homo sapiens folylpolyglutamate synthetase mRNA, complete ads TCAAATGCAT 417 37  9-68 1.60 HETEROGENEOUS NUCLEAR RIBONUCLEOPROTEINS C1/C2 TCCAAGGAAG 418 13  5-26 1.60 Homo sapiens DBI-related protein mRNA,compiete ads CCCAGGGAGA 419 49 11-90 1.60 Homo sapiens chaperonin containing t-complex polypeptide 1, delta subunit (Cctd) mRNA, complete cds TGGCCTGCCC 420 54  15-102 1.60 ESTs TGGCCTGCCC 421 54  15-102 1.60 Moderately similar to PEANUT PROTEIN [Drosophila melanogaster] GGCCAAAGGC 422 39 14-77 1.60 Human mRNA for KIAA0064 gene, complete cds GGCCTGCTGC 423 69  13-125 1.60 ESTs, Highly similar to C10 [H. sapiens] GTGAAGCTGA 424 22  7-41 1.61 ESTs, Highiy similar to HYPOTHETICAL 6.3 KID PROTEIN ZK652.2 IN CHROMOSOME III [Caenorhabditis elegans] GTGAAGCTGA 425 22  7-41 1.61 ESTs, Highly similar to thymic epithelial cell surface antigen [M. musculus] GAAATGTAAG 426 50 12-93 1.62 ESTS GAAATGTAAG 427 50 12-93 1.62 H. sapiens hnRNP-E2 mRNA CGTGTTAATG 428 73  31-148 1.62 CELLULAR NUCLEIC ACID PROTEIN AGGGGATTCC 429 19  9-40 1.62 Human arginine-rich protein (ARP) gene, complete cds CAGCTCACTG 430 186  23-326 1.63 Homo sapiens CAG-isI 7 mRNA, complete cds GTTTGGCAGT 431 35 13-70 1.63 Homo sapiens mRNA for EOF-1 protein GGAGCTCTGT 432 48 13-92 1.63 ESTs, Moderately similar to NADH-UBIQUINONE OXIDOREDUCTASE B15 SUBUNIT [Bos taurus] TGGAACTGTG 433 22  5-42 1.63 ESTs, Weakly similar to !!!! ALU SUBFAMILY SQ WARNING ENTRY !!!![H. sapiens] TCTGCTTACA 434 58  18-114 1.63 Human ribosomal protein L10 mRNA, complete cds AGGGCTTCCA 435 843  205-1257 1.64 UBIQUINOL-CYTOCHROME C REDUCTASE COMPLEX SUBUNIT VI REQUIRING PROTEIN GAGCAAACGG 436 20  5-37 1.64 Homo sapiens chromosome 19, cosmid R26445 TGTGATCAGA 437 88  27-171 1.64 Homo sapiens F1F0-type ATP synthase subunit g mRNA, complete cds ACACTACGGG 438 37  6-66 1.64 ESTs, Weakly similar to putative progesterone binding proiein [H. sapiens] AGCCAAAAAA 439 41 12-79 1.64 Homo sapiens hnRNP-E2 mRNA GCGGGTGTGG 440 16  5-32 1.64 Human methionine aminopeptidase mRNA, complete cds TTGCTAGAGG 441 39 13-78 1.65 ESTs, Weakly similar to F35H10.6 gene product [C. elegans] GGGGCTTCTG 442 15  6-30 1.65 Human mRNA for cysteine protease, complete cds AACTCTTGAA 443 45 14-87 1.65 Human translation initiation factor elF3 p40 subunit mRNA, complete cds GTCTGACCCC 444 44  8-80 1.65 PROTEIN PHOSPHATASE PP2A, 65 KD REGULATORY SUBUNm ALPHA ISOFORM ATGTCATCAA 445 48 12-92 1.65 Human clathrin assembly protein 50 (AP50) mRNA, complete cds TCTGTCAAGA 446 40 15-81 1.66 ATP synthase, H + transporting, mitochondrial F1 complex, O subunit (oligomycin sensitivity conferring protein) GCCCCAGCGA 447 23  8-46 1.66 ESTs GGCAAGCCCC 448 425 119-824 1.66 Heat shock 27kD protein 1 CTCATCAGCT 449 48 16-95 1.66 ADENYLYL CYCLASE-ASSOCIATED PROTEIN 1 CTGTTGATTG 450 137  49-276 1.66 Heterogeneous nuclear ribonucleoprotein A1 GCTTTTAAGG 451 171  27-312 1.66 40S RIBOSOMAL PROTEIN S20 GCCTGAGCCT 452 13  6-28 1.66 ESTs GAGCGGGATG 453 57  21-116 1.66 Proteasome (prosome, macropain) subunit, beta type, 6 TTCACAGTGG 454 56  13-107 1.67 Calcineurin B GCCCGTGCCA 455 23  8-46 1.67 ESTs, Highly similar to HYPOTHETICAL 38.2 KD PROTEIN IN BEM2-SPT2 INTERGENIC REGION [Saccharomyces cerevisiae] CCCTAGGTTG 456 51 14-98 1.67 Human mRNA for KIAA0315 gene, partial cds CCCTGATTTT 457 33 12-66 1.67 Human p97 mRNA, complete cds GTGTTAACCA 458 314  73-599 1.67 Human ribosomal protein L10 mRNA, complete cds AGGAAAGCTG 459 469 162-948 1.68 ESTs, Highly similar to 60S RIBOSOMAL PROTEIN L36 [Rattus norveglcus] TTCTCTCTGT 460 31  6-60 1.68 ADP-ribosylation factor 5 TTACTAAATG 461 26  5-48 1.68 Calnexin GGGTGTGGTG 462 18  5-36 1.68 ESTs CCACTGCAGT 463 14  5-29 1.68 GLYCOPROTEIN HORMONES ALPHA CHAIN PRECURSOR AGCCTGGACT 464 47 17-95 1.69 Human mRNA for Mr 110,000 antigen, complete cds GTGGGGTGAC 465 24  6-47 1.69 ESTs, Weakly similar to HYPOTHETICAL 21.5 KD PROTEIN IN SEC15-SAP4 INTERGENIC REGION [S. cerevisiae] CACTACACGG 466 46 11-88 1.69 FK506-BINDING PROTEIN PRECURSOR CTCATAGCAG 467 92  31-187 1.69 TRANSLATIONALLY CONTROLLED TUMOR PROTEIN GGAATGTACG 468 94  27-187 1.70 Human mitochondrial ATP synthase subunit 9, P3 gene copy, mRNA, nuclear gene encoding mitochondrial protein, complete cds CTGAGGGTGG 469 17  6-36 1.70 ESTs AAGGTCGAGC 470 75   9-136 1.70 60S RIBOSOMAL PROTEIN L24 GAATCACTGC 471 18  5-35 1.70 Homo sapiens ribosomal protein L33-like protein mRNA, complete cds ACATCATCGA 472 374  86-722 1.70 Ribosomal protein L12 GAATGAGGAC 473 27  6-51 1.70 Human mRNA for reticulocalbin, complete cds CCTCGCTCAG 474 44 14-89 1.70 Hydroxyacyl-Coenzyme A dehydrogenase/3-ketoacyl-Coenzyme A thiolase/enoyl-Coenzyme A hydralase (trifunctional protein), alpha subunit TCCTAGCCTG 475 16  5-33 1.70 Homo sapiens SPF31 (SPF31) mRNA, complete cds AGGTGCGGGG 476 35  5-64 1.71 Human hASNA-I mRNA, complete cds CTCCAATAAA 477 14  7-31 1.71 Homo sapiens clone 24775 mRNA sequence GCGCTGGAGT 478 73 23-147 1.71 ESTs, Wealky similar to HYPOTHETICAL 9.9 KD PROTEIN B0495.6 IN CHROMOSOME [C. elegans] AATTTGCAAC 479 21  5-40 1.71 Homo sapiens histone macroH2A1.2 mRNA, complete cds AACGCGGCCA 480 448 22-790 1.71 Macrophage migration inhibitory factor GGTGTATATG 481 21  7-42 1.71 Homo sapiens chromosome 9, P1 clone 11659 GGCAACAAAA 482 35  6-66 1.71 Human (clone E5.1) RNA-binding protein mRNA, complete cds GGCAACAAAA 483 35  6-66 1.71 Homo sapiens importin beta subunit mRNA, complete cds TTTGTGACTG 484 28 13-62 1.71 Homo sapiens phosphoprotein CIBP mRNA, complete cds ATGAGGCCGG 485 23  7-47 1.72 No match TCAGTTTGTC 486 39 15-81 1.72 Human HS1 binding protein HAX-1 mRNA, nuclear gene encoding mitochondrial protein, complete cds CCCTATTAAG 487 69  10-129 1.72 No match TTTCTAGTTT 488 55  28-123 1.72 Human mRNA for KIAA0108 gene, complete cds GGGCCCTTCC 489 20  5-40 1.72 Homo sapiens clone 24684 mRNA sequence GGGCCCTTCC 490 20  5-40 1.72 Fibulin 1 CCTTGGTTTT 491 24  6-47 1.72 Homo sapiens DNA-binding protein (CROC-1B) mRNA, complete cds GCTAAGGAGA 492 81  21-161 1.72 Human ras-related C3 botulinurn toxin substrate mRNA, complete cds TGAGGGGTGA 493 27  8-56 1.72 Human Gps1 (GPS1) mRNA, complete cds CCAGCTGCCA 494 63  19-128 1.73 Ubiqultin activating enzyme E1 GGGCTGTTTG 495 16  5-34 1.73 No match TGGACACAAG 496 18  5-36 1.73 Arginyl-tRNA sythetase TCTCCAGGAA 497 44 12-89 1.73 ESTs, Weakly similar to PUTATIVE MITOCHONDRIALCARRIER C16C10.1 [C. elegans] TGATGTTTGA 498 24  8-49 1.73 Human mRNA for KIAA0058 gene, complete cds GTGGTGCACG 499 82  13-155 1.73 No match GTCTGCACCT 500 32  8-64 1.73 ESTS, Weakly similar to NUCLEAR PROTEIN SNF7 [Saccharomyces cerevisiae] GATGACCCCG 501 32 11-66 1.73 ESTs, Weakly similar to F08G12.1 [C. elegans] ATCAAGGGTG 502 269  27-494 1.73 Ribosomal protein L9 TCTGGTCTGG 503 34 12-72 1.74 Human surface antigen mRNA, complete cds AGGATGACCC 504 42  6-79 1.74 ESTs, Weakly similar to ion channe homolog RIC [M. MUSCULUS] AAAGGGGGCA 505 28  9-58 1.74 H. sapiens mRNA for activin beta-C chain GGCTTTACCC 506 178  56-365 1.74 Eukaryotlc translation initiation factor 5A GCTTTTTAGA 507 39 10-78 1.74 Human non-histone chromosomal protein HMG-14 mRNA, complete cds CTCTGCTCGG 508 18  6-37 1.74 Homo sapiens clone 638 unknown mRNA, complete sequence GCCTGGGACT 509 58  28-130 1.74 ESTs GGTAGCAGGG 510 26  5-50 1.74 Homo sapiens clone 23930 mRNA sequence GCCGATCCTC 511 31  7-61 1.74 Homo protein mRNA, complete cds GCAGCTCAGG 512 50  13-101 1.74 Cathepsin D (lysosomal aspartyl protease) CGCAGTGTCC 513 118  20-225 1.75 Vacuolar H + ATPase proton channel subunit CCCCTATTAA 514 62  13-121 1.75 No match TTGTAAAAGG 515 23  8-47 1.75 Homo sapienschromosome 9, P1 clone 11659 CCACACCGGT 516 17  6-36 1.75 Heme oxygenase (decycling) 2 CCTGGAAGAG 517 192  60-396 1.75 Procollagen-proline, 2-oxoglutarate 4-di-oxygenase (proline 4-hydroxylase), betapolypeptide (protein disulfide isomerase; thyroid hormone binding protein p55) TAGCCGCTGA 518 37  7-72 1.75 Homo sapiens alpha SNAP mRNA, complete cds CCTAGGACCT 519 19  5-39 1.75 Homo sapiensArp⅔ protein complex subunit p20-Arc (ARC20) mRNA, complete cds GTGGACCCTG 520 26  9-54 1.75 Surfeit 1 GTGGACCCTG 521 26  9-54 175 ESTs, Weakly similar to R05G6.4 gene product [C. elegans] TTGGGAGCAG 522 32  6-63 1.76 Isoleucine-tRNA synthetase GTCTCACGTG 523 23  9-49 1.76 ESTs GTACTGTGGC 524 114  24-225 1.76 Homo sapiens nuclear chloride ion channel protein (NCC27) mRNA, complete cds AAGATAATGC 525 12  5-27 1.76 ESTs, Weakly similar to YeI007 c-ap [S. cerevisiae] AATACCTCGT 526 31  7-61 1.76 ESTs ACCTTGTGCC 527 23  6-47 1.76 ESTs, Weakly similar to alpha 2,6-sialyltransferase [R. norvegicus] ACCTTGTGCC 528 23  6-47 1.76 Sorbitol dehydrogenase GGAGGGGGCT 529 88  16-172 1.77 LAMIN A GCCTATGGTC 530 39  9-78 1.77 ESTs, Highly similar to SEX-REGULATED PROTEIN JANUS-A [Drosophila melanogaster] GTGCTGAATG 531 459  219-1031 1.77 MYOSIN LIGHT CHAIN ALKALI, SMOOTH-MUSCLE ISOFORM TCGTCGCAGA 532 37  9-75 1.77 Highly similar to NADH-UBIQUINONE OXIDOREDUCTASE SUBUNIT B14.5A [Bos taurus] GTGACAGAAG 533 178  36-351 1.77 Eukaryotic translation initiation factor 4A (eIF-4A) isoform 1 TCAACGGTGT 534 15  5-31 1.77 Homo sapiens mRNA for RanBPM, complete cds GAGCCTTGGT 535 58  11-113 1.77 Protein phosphatase 1, catalytIc subunit, alpha isoform TACATCCGAA 536 19  6-40 1.78 ESTs GTCTGTGAGA 537 29 12-84 1.78 Homo sapiens mRNA for Hrs, complete cds GTTAACGTCC 538 95  18-187 1.78 Homo sapiens Bruton's tyrosine kinase (BTK), alpha-D-galactosidase A (GLA), L44-like ribosomal protein (L44L) and FTP3 (FTP3) genes, complete cds GTGCGCTAGG 539 141  27-277 1.78 ESTs, Weakly similar to F49C12.12 [C. elegans] CGGATAAGGC 540 17  6-36 1.78 ESTs GTCTGGGGCT 541 204  49-413 1.78 SM22-ALPHA HOMOLOG CATCCTGCTG 542 64  12-125 1.78 Human mRNA for 26S proteasome subunit p97, complete cds TCACAAGCAA 543 142  52-305 1.78 H. sapiens alpha NAC mRNA GGCTGATGTG 544 73  15-146 1.78 Glycyl-tRNA synthetase CCCGTCCGGA 545 1272  293-2554 1.78 60S RIBOSOMAL PROTEIN L13 TCCGCGAGAA 546 98  33-208 1.78 ESTs, Weakly similar to SEX-DETERMINING TRANSFORMER PROTEIN 1 Caenorhabditis elegans] GTGCTGGAGA 547 98  12-187 1.79 Human SnRNP core protein Sm D2 mRNA, complete cds TCCTCAAGAT 548 28  8-54 1.79 Human enhancer of rudimentary homolog mRNA, complete cds CAACTTAGTT 549 60 20-127 1.79 Human myosin regulatory light chain mRNA, complete cds GGGCAGCTGG 550 35 12-75 1.79 ESTs TTTCAGAGAG 551 43  8-84 1.79 Human calmodulin mRNA, complete cds TTTCAGAGAG 552 43  8-84 1.79 Signal recognition particle 9 kD protein GACGCAGAAG 553 17  6-36 1.79 ESTs, Highly similar to ALPHA-ADAPTIN [Mus musculus] GGAAGTTTCG 554 35  9-72 1.79 ESTs, Weakly similar to similar to oxysterol-binding proteins: partial CDS [C. elegans] GTTGCTGCCC 555 34  5-65 1.79 Homo sapiens mRNA for putative seven transmembrane domain protein GCTGGGGTGG 556 21  6-44 1.79 H. sapiens mRNA for mediator of receptor-induced toxicity CTCAACATCT 557 456  99-918 1.80 Ribosomal protein, large, P0 CAAGCAGGAC 558 42  8-84 1.80 ESTs, Weakly similar to transmembrane protein [H. sapiens] TTGGCTTTTC 559 27  8-57 1.80 ESTs TGGCAACCTT 560 38 17-85 1.80 ESTs, Highly similar to GLUTATHIONE S-TRANSFERASE, MITOCHONDRIAL [Rattus norvegicus] GCATAATAGG 561 391  83-786 1.80 Ribosomal protein L21 GGGGGTAACT 562 43  9-88 1.80 RNA-BINDING PROTEIN FUS/TLS CCTTCGAGAT 563 274  55-549 1.80 Ribosomal protein S5 CGGGCCGTGC 564 18  6-38 1.80 H. sapiens mRNA for Glyoxalase II GTGTTGCACA 565 210  42-421 1.80 Ribosomal protein S13 CCTCGGAAAA 566 158  27-312 1.81 60S RIBOSOMAL PROTEIN L38 AATAAAGGCT 567 56   9-110 1.81 Myosin, light polypeptide 3, alkali; ventricular, skeletal, slow AATAAAGGCT 568 56   9-110 1.81 Aplysia ras-related homolog 9 CTTCTGTGTA 569 21  9-47 1.81 Homo sapiens immunophilin homolog ARA9 mRNA, complete cds CTTCTGTGTA 570 21  9-47 1.81 Human mRNA for KIAA0190 gene, partial cds GGTCCAGTGT 571 144  26-286 1.81 Phosphoglycerate mulase 1 (brain) AGCACCTCCA 572 701  197-1467 1.81 Eukaryotic translation elongation factor 2 AAGCTGAGTG 573 39 12-82 1.81 Human M4 protein mRNA, complete cds GTTTCTTCCC 574 27 11-80 1.81 ESTs TGAGGGAATA 575 191  51-397 1.82 Triosephosphate isomerase 1 AGCTCTCCCT 576 447 150-962 1.82 60S RIBOSOMAL PROTEIN L23 TACGTTGCAG 577 18  8-40 1.82 Homo sapiens GC20 protein mRNA, complete cds GGGTGTGTAT 578 16  6-35 1.82 Homo sapiens anglo-associated migratory cell protein (AAMP) mRNA, complete cds GGAGGGATCA 579 37 12-79 1.82 Homo sapiens Integrin-linked kinase (ILK) mRNA, complete cds ATCAGTGGCT 580 64  25-143 1.82 PROTEASOME BETA CHAIN PRECURSOR CCCCCTGCCC 581 57  17-121 1.83 ESTs CCCCCTGCCC 582 57  17-121 1.83 ESTs CAAAAAAAAA 583 94   8-180 1.83 Cholinergic receptor, nicotinic, alpha polypeptide 3 ACCTGCCGAC 584 18  5-37 1.83 Homo sapiens growth suppressor related (DOC-1R) mRNA, complete cds GACCAGAAAA 585 81  17-165 1.83 CYTOCHROME C OXIDASE POLYPEPTIDE VIA-LIVER PRECURSOR AGCCACTGCG 586 33  9-69 1.83 No match TTGAGCCAGC 587 43  21-101 1.83 Human KH type splicing regulatory protein KSRP mRNA, complete cds TTTCAGGGGA 588 51   9-103 1.84 ESTs, Moderately similar to N-methyl-D-aspartate receptor glutamate-binding chain [R. norvegicus] TCCGGCCGCG 589 75  32-169 1.84 ESTs GTGATCTCCG 590 22  6-46 1.84 ESTs CTGCTGAGTG 591 46  6-90 1.84 ESTs, Highly similar to HYPOTHETICAL 14.1 KD PROTEIN C31A2.02 IN CHROMOSOME I [Schizosaccharomyces pombe] CTGCTTAAGG 592 16  8-36 1.84 ESTs, Highly similar to HYPOTHETICAL 68.7 KD PROTEIN ZK757.1 IN CHROMOSOME III [Caenorhabdtls elegans] TGTGGCCTCC 593 33 14-74 1.84 ESTs, Weakly similar to No definition line found [C. elegans] CGTTTTCTGA 594 20  6-43 1.84 Human protein-tyrosine phosphatase (HU-PP-1) mRNA, partial sequence GGAAAAAAAA 595 97   8-187 1.84 Hepatocyte growth factor (hepapoletin A; scatter factor) GGAAAAAAAA 596 97   8-187 1.84 ESTs, Highly similar to ATP SYNTHASE EPSILON CHAIN, MITOCHONDRIAL PRECURSOR [Bos taurus] GAGGGAGTTT 597 548  162-1172 1.84 Ribosomal protein L27a GACTCACTTT 598 156  27-315 1.84 Peptidylprolyl isomerase B (cyclophilin B) GAGAACGGGG 599 33  7-67 1.85 ESTs, Highly similar to CORONIN [Dictyostelium discoideum] TGGCTAGTGT 600 57  20-125 1.85 Human mRNA for proteasome subunit z, complete cds CTGTCATTTG 601 20  5-42 1.85 PRE-MRNA SPLICING FACTOR SRP20 GTTCCCTGGC 602 320  98-690 1.85 Finkel-Biskis-Reilly murine sarcoma virus (FBR-MuSV) ubiquitously expressed (fox derived) GCATTTAAAT 603 76   7-148 1.85 ELONGATION FACTOR 1-BETA ATCCACATCG 604 69  17-144 1.85 ESTs, Weakly similar to CASEIN KINASE I HOMOLOG HRR25 [Saccharomyces cerevisiae] CTGCTGTGAT 605 29  6-59 1.85 Human mRNA for U1 small nuclear RNP-specific C protein GTGACCTCCT 606 116  38-253 1.85 CYTOCHROME C OXIDASE POLYPEPTIDE VIII-LIVER/HEART PRECURSOR GTGGACCCCA 607 47  9-97 1.86 Human siah binding proteIn 1 (SiahBP1) mRNA, partial cds GACTAGTGCG 608 18  6-39 1.86 ESTs TTATGGGATC 609 247  31-490 1.86 GUANINE NUCLEOTIDE-BINDING PROTEIN BETA SUBUNIT-LIKE PROTEIN 12.3 TTTCAGATTG 610 29  5-60 1.86 Human transcriptional coactivator PC4 mRNA, complete cds GTCTGAGCTC 611 58  14-122 1.86 ESTs, Weakly similar to HYPOTHETICAL 15.4 KD PROTEIN C16C10.11 IN CHROMOSOME III [C. elegans ] CACACAATGT 612 22  9-49 1.86 Homo sapiens peroxisomal phytanoyi-CoA alpha-hydroxylase (PAHX) mRNA, complete cds CACACAATGT 613 22  9-49 1.86 Cytochrome c oxidase subunit IV ACCCCACCCA 614 28  6-55 1.86 H. sapiens mRNA for 1-acylglycerol-3-phosphate O-acyltransferase GGAGGCAGGT 615 31  9-67 1.86 Homo sapiens chromosome 1p33-p34 beta-1,4-galactosyltransferase mRNA, complete cds TCTCAATTCT 616 27  8-58 1.87 Cell division cycle 42 (GTP-bindlng protein, 25 kD) CTCTTCAGGA 617 19  6-40 1.87 Homo sapiens phosphomevalonate kinase mRNA, complete cds CTGGGACTGC 618 18  7-40 1.87 Homo sapiens mRNA for follistain-related protein (FRP), complete cds GCCCAGCAGG 619 26  8-57 1.87 ESTs GCCCAGCAGG 620 28  8-57 1.87 ESTs GGGCCAGGGG 621 44 16-98 1.87 ESTs GGGGGACGGC 622 42 12-89 1.87 ESTs, Weakly similar to Y48E1B.1 [C. elegans] ACTGGGTCTA 623 154  29-317 1.87 Non-metastatic cells 2, protein (NM23B) expressed in GCCGAGGAAG 624 778  113-1570 1.87 Human mRNA for ribosomal protein S12 CAGATCTTTG 625 90  14-182 1.88 Ublquitin A-52 residue ribosomal protein fusion product 1 AGGTTTCCTC 626 21  6-45 1.88 Homo sapiens mRNA for proteasome subunit p58, complete cds CCGTCCAGG 627 532   59-1058 1.88 Ribosomal protein S16 GTGGCGGGCG 628 81  21-174 1.88 Biliary glycoprotein GTGGCGGGCG 629 81  21-174 1.88 Homo sapiens malignancy-associated protein mRNA, partial cds GTGGCGGGCG 630 81  21-174 1.88 Homo sapiens mRNA for KIAA0565 protein, complete cds GGCAAGAAGA 631 252  34-507 1.88 Ribosomal protein L27 TCTTTACTTG 632 23  6-49 1.88 Homo sapiens Arp⅔ protein complex subunit p21-Arc (ARC21) mRNA, complete cds CTCCTCACCT 633 255  56-536 1.88 60S RIBOSOMAL PROTEIN L13A CTCCTCACCT 634 255  58-536 1.88 Human Bak mRNA, complete cds GCCTGTATGA 635 392 116-853 1.88 Ribosomal protein S24 GCTTTATTTG 636 560  147-1203 1.88 Human mRNA fragment encoding cytoplasmic actin. (isolated from cultured epidermal cells grown from human foreskin CTTAAGGATT 637 27  9-60 1.88 ESTs, Highly similar to transcription factor ARF6 chain B [M. musculus] GGATTTGGCC 638 856  165-1401 1.88 Ribosomal protein, large P2 GGATTTGGCC 639 856  165-1401 1.88 Ribosomal protein S26 GGATTTGGCC 640 656  165-1401 1.88 Human for PIG-B, complete cds TCCTCCTCCCC 641 31  5-62 1.89 Human mRNA for proteasome subunit HsC7-1, complete cds GGCCCTCTGA 642 46  9-96 1.89 Human peptidyl-prolyl isomerase and essential mitotic regulator (PIN1) mRNA, complete cds TGGCTGTGTG 643 47  8-97 1.89 ESTs AGACCAAAGT 644 38  6-79 1.89 DNAJ PROTEIN HOMOLOG 1 ATGGCCAACT 645 28 12-64 1.89 ESTs AGGAGCTGCT 646 81  12-165 1.89 ESTs AGGAGCTGCT 647 81  12-165 1.89 Human mitochondrial NADH dehydrogenase-ubiquinone Fe—S protein 8, 23 kDa subunit precursor (NDUFS8) nuclear mRNA encoding mitochondrial protein, complete cds TGTACCTGTA 648 245   8-473 1.90 Human alpha-tubulin mRNA, complete cds GATCCCAACA 649 70  11-143 1.90 ATP synthase, H + transporting mitochondrial F1 complex, beta polypeptide GGCCATCTCT 650 38  8-80 1.90 14-3-3 PROTEIN TAU AGGTGCAGAG 651 28  9-58 1.90 Homo sapiens pescadillo mRNA, complete cds GTGGCATCAC 652 32  7-68 1.90 ESTs, Weakly similar to C25A1.6 [C. elegans] TGTGTTGAGA 653 1663  321-3487 1.90 Translation elongation factor 1-alpha-1 CTGAGACAAA 654 98  14-199 1.91 Basicc transcription factor 3 GCAACGGGCC 655 54   8-108 1.91 Homo sapiens mRNA for brain acyl-CoA hydrolase, complete cds GCTGGCTGGC 656 113  27-243 1.91 Homo sapiens chaperonin containing t-complex polypeptide 1, eta subunit (Ccth) mRNA, complete cds GCCAAGATGC 657 55  11-116 1.91 ESTs GCCAAGGGGC 658 28  8-61 1.91 Oxoglutarate dehydrogenase (lipoamide) ACGGTGATGT 659 37 11-81 1.91 ESTs CCCATCCGAA 660 353  77-753 1.91 Ribosomal protein L26 ACAAACTTAG 661 60  24-139 1.91 Human calmodulin mRNA, complete cds GCCTCCTCCC 662 94  23-203 1.92 ESTs GTGCCTGAGA 663 72  10-149 1.92 LAMIN A TCCAATACTG 664 22  5-47 1.92 Human dynamitin mRNA, complete cds GTGGTGCGTG 665 39 11-86 1.92 Homo sapiens X-ray repair cross-complementing protein 2 (XRCC2) mRNA, complete cds AAGAAGCAGG 666 38 15-88 1.92 Homo sapiens unknown mRNA, complete cds ACTTGGAGCC 667 42 13-95 1.92 Human calmodulin mRNA, complete cds CCGTGGTCAC 668 88  15-185 1.92 H. sapiens mRNS for clathrin-associated protein ACAGTGGGGA 669 65  21-146 1.92 Human (p23) mRNA, complete cds ACAAACTGTG 670 69  22-154 1.92 H. sapiens mRNA for Sop2p-like protein GTCTTAACTC 671 23  6-50 1.93 Homo sapiens Dim 1p homolog (hdlm 1 + ) mRNA, complete cds CTGTGCTCGG 672 34 11-77 1.93 ENOYL-COA HYDRATASE, MITOCHONDRIAL PRECURSOR GTGGCCTGCA 673 22  5-46 1.93 ESTs, Weakly similar to K01G5.8 [C. elegans] TGGTACACGT 674 100  43-236 1.93 Human calmodulin mRNA, complete cds GTACTGTATG 675 23  9-54 1.93 ESTs GTACTGTATG 676 23  9-54 1.93 Homo sapiens importin beta subunit mRNA, complete cds GGCCAGGTGG 677 25  5-53 1.93 Homo sapiens calmodulin-stimulated phosphodiesterase PDE1B1 mRNA, complete cds GGCCAGGTGG 678 25  5-53 1.93 Metallopeptidase 1 (33 kD) AGGGAGAGGG 679 20  5-43 1.93 Homo sapiens forkhead protein FREAC-2 mRNA, complete cds AGGGAGAGGG 680 20  5-43 1.93 Ferritin heavy chain AGGGAGAGGG 681 20  5-43 1.93 UBIQUITIN CARBOXYL-TERMINAL HYDROLASET GTGGCAGGTG 682 100  19-213 1.93 Human mRNA for KIAA0340 gene, partial cds TCTTGTGCAT 683 143  26-302 1.93 L-LACTATE DEHYDROGENASE M CHAIN CCACACACCG 684 21  8-49 1.94 ESTs, Highly similar to HYPOTHETICAL 43.2 kD PROTEIN C34E10.1 IN CHROMOSOME III [Caenorhabditis elegans] ACAAATCCTT 685 45  7-95 1.94 FK506-binding protein 1 (12 kD) GTGAGACCCC 686 45 11-98 1.94 No match AAAGCCAAGA 687 29 10-67 1.94 Electron-transfer-flavoprotein, beta polypeptide CAAGGATCTA 668 27 12-65 1.94 Fibroblast growth factor receptor 2 TGAGGCCAGG 689 47  15-107 1.94 High mobility group box TTTTGTGTGA 690 16  5-37 1.94 ESTs, Weakly similar to 50S RIBOSOMAL PROTEIN L20 [E. coli] ACAGTCTTGC 691 17  6-38 1.94 CYTOCHROME P450 IVF3 ACAGTCTTGC 692 17  6-38 1.94 Human mRNA for KIAA0102 gene, complete cds CCAGGCACGC 693 40  9-87 1.95 Human HXC-26 mRNA, complete cds AGTTTCCCAA 694 40  21-100 1.95 Homo sapiens SULT1C sulfotransferase (SULT1C) mRNA, complete cds CCAGTGGCCC 695 274  48-582 1.95 Ribosomal protein S9 GCCCCGCCCT 696 30 11-69 1.95 Homo sapiens chromosome 19, cosmid R32184 TCTCTACTAA 697 41  6-85 1.95 Tropomyosin 4 (fibroblast) CGGCTTTTCT 698 32  9-71 1.95 Spectrin, beta non-erythrocytic 1 TGGCCCCCGC 699 28  6-56 1.95 ESTs TGGCCCCCGC 700 26  6-56 1.95 Human helix-loop-helix zipper protein mRNA CTCCTGGGGC 701 48   6-101 1.95 ESTs AAGGAGCTGG 702 16  5-37 1.96 ESTs, Highly similar to YME1 PROTEIN [Saccharomyces cerevisiae] AAGGAGCTGG 703 16  5-37 1.96 ESTs AAGGAGCTGG 704 18  5-37 1.96 Homo sapiens clone lambda MEN1 region unknown protein mRNA, complete cds GGCTTTGATT 705 18  5-40 1.96 COATOMER BETA′ SUBUNIT ACTACCTTCA 706 27  8-81 1.96 ESTs, Weakly similar to B0334.4 [C. elegans] CTGTGCATTT 707 33 11-75 1.96 Human 54 kDa protein mRNA, complete cds ACTCCAAAAA 708 210  40-452 1.96 Human insulinoma rig-analog mRNA encoding DNA-binding protein, complete cds ACTCCAAAAA 709 210  40-452 1.96 H. sapiens mRNA for transmembrane protein mp24 TCCTGCCCCA 710 72  14-155 1.96 Parathymosin TCCTGCCCCA 711 72  14-155 1.96 Homo sapiens mRNA for KIAA0511 protein, partial cds AAGCTGGAGG 712 56  15-125 1.96 Human translation initiation factor elF3 p66 subunit mRNA, complete cds GCACAAGAAG 713 90  19-195 1.96 ESTs GAAACCGAGG 714 47  11-104 1.97 ESTs, Weakly similar to HYPOTHETICAL 16.8 KD PROTEIN IN SMY2-RPS101 INTERGENIC REGION [S.cerevislae] GAAACCGAGG 715 47  11-104 1.97 Human mRNA for KIAA0029 gene, parial cds GCCCGCAAGC 716 16  5-36 1.97 H. sapiens HUNKI mRNA CTTTCAGATG 717 44 12-98 1.97 Phosphofructokinase, platelet GGGCGCTGTG 718 117  30-260 1.97 Homo sapiens mRNA for smallest subunit of ubiquinoi-cytochrome c reductase, complete cds GTATTCCCCT 719 36  8-79 1.97 Homo sapiens poly(A) binding protein II (PABP2) gene, complete cds GTATTCCCCT 720 36  8-79 1.97 ESTs, Highly similar to elastin like protein [D.melanogaster] CTGGCCATCG 721 19  6-43 1.98 ESTs GTGGTGGACA 722 33  6-72 1.98 Human nicotinic acetylcholine receptor alpha6 subunit precursor mRNA, complete cds GTGGTGGACA 723 33  6-72 1.98 Homo sapiens mRNA for PBK1 protein GTGGTGGACA 724 33  6-72 1.98 Breast cancer 1, early onset CACCTAATTG 725 1247 410-28  1.98 Tag matches mitochondrial sequence GACCCCTGTC 726 18  6-41 1.98 Homo sapiens (clone s153) mRNA fragment CCCTTAGCTT 727 47  21-114 1.98 Human mRNA for myosin regulatory light chain CAGAGACGTG 728 30  9-68 1.98 Human dystroglycan (DAG1) mRNA, complete cds ATGGCTGGTA 729 1064  174-2287 1.98 40S RIBOSOMAL PROTEIN S2 TCAGCCTTCT 730 46  14-108 1.99 Homo sapiens flotillin-1 mRNA, complete cds TCGTAACGAG 731 23  9-54 1.99 ESTs GCGACGAGGC 732 178  17-371 1.99 60S RIBOSOMAL PROTEIN L38 GCGGGGTACC 733 59  17-133 1.99 Human mRNA for pM5 protein TCCTTCTCCA 734 58  12-128 1.99 ALPHA-ACTININ 1, CYTOSKELETAL ISOFORM CAGTCTCTCA 735 107  16-229 1.99 Ribosomal protein S10 ACCCTTCCCT 736 56  12-124 1.99 ESTs, Weakly similar to VON EBNERS GLAND PROTEIN PRECURSOR [H. sapiens] ACCCTTCCCT 737 56  12-124 1.99 Signal sequence receptor, beta TGAGTGGTCA 738 20  7-47 1.99 ESTs, Highly similar to HYPOTHETICAL 13.6 KD PROTEIN IN NUP17O-ILS1 INTERGENIC REGION [Saccharomyces cerevislae] GACAATGCCA 739 46  11-107 1.99 Human mRNA for ATP synthase gamma-subunit (L-type), complete cds ATCTTTCTGG 740 80  15-176 2.00 Tyrosine 3-monooxygenase/tryptophan 5-monooxygenase activation protein, zeta polypeptide AGCTGTCCCC 741 23  5-50 2.00 Tag matches mitochondrial sequence TCTTCCAGGA 742 52  11-114 2.00 Human ribosomal protein L10 mRNA, complete cds GTGCCTAGGA 743 29  9-67 2.00 ESTs TGGACCCCCC 744 26  6-57 2.00 ESTs, Weakly similar to K04G2.2 [C. elegans] ACCTGTATCC 745 158  24-341 2.00 INTERFERON-INDUCIBLE PROTEIN 1-8U ACCTGCTGGT 746 17  6-40 2.00 Homo sapiens clone 23675 mRNA sequence AGTCTGATGT 747 39  5-84 2.00 ESTs, Weakly similar to weak similarity to rat TEGT protein [C. elegans] TCTCTACCCA 748 71  27-169 2.00 Amyloid beta (A4) precursor-like protein 2 TGATTAAGGT 749 26  6-58 2.00 HEAT SHOCK FACTOR PROTEIN 1 CAGCAGAAGC 750 191  75-459 2.01 Homo sapiens 4F5rei mRNA, complete cds TCCCTATTAA 751 5970   987-12977 2.01 No match GTGGAGGTGC 752 42  6-91 2.01 Human 100 kDa coactivator mRNA, complete cds AAGATCCCCG 753 63  15-142 2.01 Homo sapiens DNA sequence from cosmid ICK0721Q on chromosome 6. GAGCGGCCTC 754 29  9-68 2.01 Human ORF mRNA, complete cds AACTACATAG 755 21  9-50 2.02 ESTs GTAAGATTTG 756 33  9-76 2.02 Human 150 kDa oxygen-regulated protein ORP150 mRNA, complete cds AGCCTGCAGA 757 65  17-147 2.02 Homo sapiens chromosome 19, cosmid R33729 GGACCACTGA 758 498  174-1182 2.02 Ribosomal protein L3 TTCAATAAAA 759 377  51-813 2.02 TRANSCOBALAMIN I PRECURSOR TTCAATAAAA 760 377  51-813 2.02 Ribosomal protein, large, P1 CGATGGTCCC 761 55   9-120 2.02 Human B-cell receptor associated protein (hBAP) mRNA, partial cds CATTTGTAAT 762 142  23-309 2.02 Tag matches mitochondrial sequence CCTGAGCCCG 763 60  14-135 2.03 ESTs, Weakly similar to ALBUMIN B-32 PROTEIN [Zea mays] TGAGGCCTCT 764 29  6-65 2.03 ESTs AAGAGTTACG 765 17  8-43 2.03 ESTs, Highly similar to 50S RIBOSOMAL PROTEIN L2 [Bacillus stearothermophilus] GAATCCAACT 766 46   6-100 2.03 ESTs AGGGGCGCAG 767 29  8-67 2.03 Human SH3-containing protein EEN mRNA, complete cds GCTTAGAAGT 768 31  6-69 2.03 HEAT SHOCK PROTEIN HSP 90-ALPHA AAGTCATTCA 769 31 10-74 2.03 Homo sapiens NADH-ubiquinone oxidoreductase subunit Cl-B14 mRNA, complete cds AAGTCATTCA 770 31 10-74 2.03 H. sapiens mRNA for proc protein TACCCCACCC 771 57  17-132 2.03 ESTs TACCCCACCC 772 67  17-132 2.03 Human zinc finger protein (MAZ) mRNA CCTAGCTGGA 773 511  132-1172 2.03 PEPTIDYL-PROLYL CIS-TRANS ISOMERASE A TCGTCTTTAT 774 126  18-275 2.04 40SR RIBOSOMAL PROTEIN S7 GGTTTGGCTT 775 70  14-156 2.04 UBIQUINOL-CYTOCHROME C REDUCTASE COMPLEX 11 KO PROTEIN PRECURSOR TAGGATGGGG 776 88  28-207 2.04 Sodium/potassium-transporting ATPase beta-3 subunit GTGCATCCCG 777 43  16-105 2.04 Casein kinase 2, beta polypeptide CAGCGCTGCA 778 37 11-87 2.04 Human CDC37 homolog mRNA, complete cds GGGAGCCCCT 779 55  12-125 2.04 ESTs, Highly similar to BETA-ARRESTIN 2 [Homo sapiens] GGGAGCCCCT 780 55  12-125 2.04 ESTs GAAGATGTGG 781 58   6-125 2.04 Homo sapiens clone 23967 unknown mRNA, partial cds CCTACCACAG 782 21  9-52 2.05 ESTs, Highly similar to GOLIATH PROTEIN [Drosophila melanogaster] TGCTAAAAAA 783 26  9-61 2.06 Myosin, heavy polypeptide 9, non-muscle CACAGAGTCC 784 28  7-64 2.06 Low density lipoprotein-related protein-associated protein 1 (alpha-2-macroglobulin receptor-associated protein 1 GGGCCAATAA 785 30  8-70 2.06 Untitled GCCTGCTGGG 786 220  49-503 2.07 Phospholipid hydroperoxide glutathione peroxidase ACTGCTTGCC 787 52  12-118 2.07 S-ADENOSYLMETHIONINE SYNTHETASE GAMMA FORM ACTGCTTGCC 788 52  12-118 2.07 [H. sapiens mRNA for Sop2p-like protein CGGTTACTGT 789 81  20-187 2.07 Homo sapiens NADH:ubiquinone oxidoreductase NDUFS6 subunit mRNA, nuclear gene encoding mitochondrial protein, complete cds AACCCGGGAG 790 179  50-420 2.07 Homo sapiens KIAA0408 mRNA, complete cds AACCCGGGAG 791 179  50-420 2.07 Cytokin receptor family II, member 4 ACCCGGGAG 792 179  50-420 2.07 H. sapiens mRNA for delta 4-3-oxosteroid 5 beta-reductase ATTAACAAAG 793 98  18-220 2.07 Guanine nucleotide binding protein (G protein), alpha stimulating activity polypeptide 1 TTCAGTGCCC 794 18  6-43 2.07 ESTs, Weakly similar to GLUCOSE-6-PHOSPHALASE [Rattus norvegicus] CCGTGCTCAT 795 51  18-123 2.07 ESTs, Highly similar to ADIPOCYTE P27 PROTEIN [Mus musculus] ATCCCTCAGT 796 78  24-184 2.07 Activating transcription factor 4 (tax-responsive enhancer element B67) TACCATCAAT 797 864  194-1985 2.07 Glyceraldehyde-3-phosphate dehydrogenase TGCACCACAG 798 34 14-84 2.08 Homo sapiens signal peptidase complex 18 kDa subunit mRNA, partial cds GAACCCTGGG 799 48   9-104 2.08 ESTs GCCGTGTCCG 800 542   60-1185 2.08 Human ribosomal protein S6 mRNA, completecds ATAGAGGCAA 801 28  7-65 2.08 Human mRNA for KIAA0026 gene, complete cds ATTGTTTATG 802 83  11-184 2.08 Human non-histone chromosomal protein HMG-17 mRNA, complete cds TAATAAAGGT 803 229  46-523 2.09 40S RIBOSOMAL PROTEIN S8 GGGATCAAGG 804 26  7-61 2.09 ESTs, Weakly similar to coded for by C. elegans cDNA yk15718.5 [ C. elegans] CAAGGGCTTG 805 28  8-68 2.09 ESTs, Highly similar to RAS-RELATED PROTEIN RAP-1B [Homo sapiens; Bos taurus] TGGTGTTGAG 806 828  147-1876 2.09 Human DNA sequence from clone 1033B10 on chromosome 6p21.2-21.31. GAGTGAGTGA 807 19  8-48 2.09 ESTs, Weakly similar to C44C1.2 gene product [C. elegans] GTGGCGCACA 808 42  9-98 2.09 Human mRNA for KIAA0072 gene, partial cds ATGATCCGGA 809 22  5-52 2.10 ATPase, Ca⁺⁺ transporting, cardiac muscle, slow twitch 2 AACCTGGGAG 810 108  37-263 2.10 Human DNA fragmentation factor-45 mRNA, complete cds AACCTGGGAG 811 108  37-263 2.10 Homo sapiens mRNA for KIAA0563 protein, complete cds TGCTTCATCT 812 53   9-120 2.10 Homo sapiens androgen receptor associated protein 24 (ARA24) mRNA, complete cds ATAATTCTTT 813 205  37-467 2.10 Ribosomal protein S29 GTTCAGCTGT 814 41  9-95 2.10 Voltage-dependent anion channel 2 GGGAAGTCAC 815 22  5-50 2.10 Human FX protein mRNA, complete cds GGGTGCTTGG 816 26  8-63 2.10 Human mRNA for ORF, Xq terminal portion CAGTTACTTA 817 52  11-120 2.10 Tyrosine 3-monooxygenase/tryptophan 5-monooxygenase activation protein, beta polypeptide GCGAAACCCC 818 207  70-506 2.10 Human G protein-coupled receptor (STRL22) mRNA, complete cds GCCTTCCAAT 819 85  11-191 2.11 P68 PROTEIN CCCCCTGGAT 820 485   33-1056 2.11 Cell division cycle 2-like 1 (PITSLRE proteins) GACCTCCTGC 821 21  5-49 2.12 Homo sapiens mRNA for kinesin-like DNA binding protein, complete cds GACCTCCTGC 822 21  5-49 2.12 Human SH3 domain-containing proline-rich kinase (sprk) mRNA, complete cds CAGCAGTAGC 823 23  6-55 2.12 H. sapiens mRNA for 218 kD Mi-2 protein TTCATTATAA 824 47   8-108 2.12 Prothymosin alpha CCCCCACCTA 825 64  15-150 2.12 INTESTINAL MEMBRANE A4 PROTEIN GGTGGATGTG 826 30  6-69 2.12 Homo sapiens methyl-CpG binding protein MBD3 (MBD3) mRNA, complete cds TCTGGTTTGT 827 41  5-91 2.12 Homo sapiens mRNA for integral membrane protein Tmp21-I (p23) TCTGGTTTGT 828 41  5-91 2.12 THYMOSIN BETA-10 CGCCTGTAAT 829 45   8-111 2.13 CDC21 HOMOLOG TCCTGCTGCC 830 45   5-101 2.13 ESTs TCCTGCTGCC 831 45   6-101 2.13 ESTs, Weakly similar to F46F6.1 [C. elegans] GTGTGGTGGT 832 27  6-64 2.13 Homo sapiens mRNA for GDP dissociation inhibitor beta TGATGTCCAC 833 10  5-27 2.14 ESTs CCAGGAGGAA 834 222  77-551 2.14 HEAT SHOCK COGNATE 71 KD PROTEIN GTGAAGCCCC 835 42  9-99 2.14 No match GGGAGCCCGG 836 32  7-75 2.15 Homo sapiens herpesvirus entry protein B (HVEB) mRNA, complete cds GCCATCCCCT 837 64  14-150 2.15 Tag matches mitochondrial sequence CAGTTGGTTG 838 28  8-69 2.15 Homo sapiens mRNA for E1B-55 kDa-associated protein ATCCATCTGT 839 21  9-54 2.15 H. sapiens hnRNP-E2 mRNA GCCAGGAAGC 840 32  6-75 2.15 ESTS, Weakly similar to C01A2.5 [C. elegans] TCCAGCCCCT 841 32  9-78 2.15 ESTs, Weakly similar T08G11.1 [C. elegans] GCCCCCCACT 842 24  6-58 2.15 Human MAP kinase activated protein kinase 2 mRNA, complete cds TGTCTGTGGT 843 18  5-45 2.15 H. sapiens BATi mRNA for nuclear RNA helicase (DEAD family) TCCCGTACAT 844 258  37-592 2.15 No match GTGGTGGGCA 845 61  12-144 2.15 Cholinergic receptor, nicotinic, delta polypeptide GTGGTGGGCA 846 61  12-144 2.15 Isovaleryl Coenzyme A dehydrogenase GTGGTGGGCA 847 61  12-144 2.15 Homo sapiens Josephln MJD1 mRNA, complete cds CTGTTAGTGT 848 54  13-130 2.16 MALATE DEHYDROGENASE, CYTOPLASMIC CTCTCACCCT 849 68  28-175 2.16 Ribonuclease/anglogenin inhibitor TGCTGGTGTG 850 30  8-74 2.16 Human mRNA, clone HH1O9 (screened by the monoclonal antibody of insulin receptor substrate-1 (IRS-1)) CTAAGACTTC 851 1455  317-3462 2.16 Tag matches mitochondrial sequence GGAAGGACAG 852 39  5-90 2.16 ATPase, H + transporting, lysosomal (vacuolar proton pump) 31 kD GAAGTGTGTC 853 23  9-60 2.16 ESTs, Highly similar to HYPOTHETICAL 37.2 KD PROTEIN C12C2.09C IN CHROMOSOME I [Schizosaccharomyces pombe] GTACCCGGAC 854 33  9-81 2.17 ESTs, Weakly similar to W08E3.1 [C. elegans] CCTCCCTGAT 855 35 10-88 2.17 Homo sapiens dynamin (DNM) mRNA, complete cds TCATCTTCAA 856 19  5-46 2.17 CALRETICULIN PRECURSOR TCATCTTCAA 857 19  5-46 2.17 ESTs TCATCTTCAA 858 19  5-48 2.17 RAB6, member RAS oncogene family ATGTACTCTG 859 38  6-89 2.17 IMP (inosine monophosphate) dehydrogenase 2 CGCCGGAACA 860 648  123-1530 2.17 Ribosomal protein L4 AAGGGAGGGT 861 78  14-184 2.17 Human phosphotyrosine independent ligand p62 for the Lck 5H2 domain mRNA, complete cds GAAAAAAAAA 862 112  12-255 2.17 Cell division cycle 10 (homologous to CDC10 of S. cerevisiae AAACTCTGTG 863 27  6-64 2.18 Homo sapiens p120 catenin isoform 1A (CTNND1) mRNA, alternatively spliced, complete cds ACACACGCAA 864 22  8-56 2.18 ESTs CCGCCGAAGT 865 50   7-116 2.18 Ribosomal protein L12 TGTGCTAAAT 866 169  46-415 2.18 60S RIBOSOMAL PROTEIN L34 CGACCGTGGC 867 24  6-57 2.18 ESTs GCCTGGGCTG 868 44  18-114 2.18 ESTs GCCTGGGCTG 869 44  18-114 2.18 Homo sapiens molybdopterin synthase sulfurylase (MOCS3) mRNA, complete cds AAAGTCAGAA 870 24 12-65 2.19 Ubiqutnol cytochrome c reductase core protein II TGGAGCGCTA 871 31  5-71 2.19 ESTs, Weakly similar to PUTATIVE MITOCHONDRIAL CARRIER C16C10.1 [C. elegans] GAAATGATGA 872 70  14-167 2.19 Homo sapiens mRNA for c-myc binding protein, complete cds TGTCGCTGGG 873 73  14-173 2.19 C4/C2 activating component of Ra-reactive factor GCCCCTGCCT 874 39  6-91 2.19 Homo sapiens DNA-binding protein (CR00-1B) mRNA, complete cds GCCCCTGCCT 875 39  6-91 2.19 Glutathione S-transferase M4 CAGGCCTGGC 876 20  7-50 2.19 ESTs CAGGCCTGGC 877 20  7-50 2.19 ESTs GCAAAAAAAA 878 153  35-371 2.20 No match AGCCACCACG 879 33  8-81 2.20 Human mRNA for KIAA0149 gene, complete cds GAGGAAGAAG 880 52  16-130 2.20 Homologue of mouse tumor rejection antigen gp96 CAGCTGTAGT 881 20  9-54 2.20 Human mRNA for KIAA0174 gene, complete cds TCTTCTCCCT 882 40 10-99 2.20 Human mRNA for hepatoma-derived growth factor, complete cds TACATTCTGT 883 30  7-74 2.20 Myeloid cell leukemia sequence 1 (BCL2-related) GGGAAACCCC 884 39 11-98 2.21 ESTs, Weakly similar to HYPOTHETICAL 68.7 KD PROTEIN ZK757.1 IN CHROMOSOME III [C. elegans] AGCCACTGCA 885 67   8-155 2.21 Homo sapiens mRNA for 26S proteasome subunit p55, complete cds TAGTTGAAGT 886 55  13-136 2.21 UBIQUINOL-CYTOCHROME C REDUCTASE COMPLEX 14 KD PROTEIN GCCAAGTTTG 887 17  5-43 2.21 Human mRNA for proteasome subunit p112, complete cds GGCGGCTGCA 888 36  9-89 2.21 Excision repair cross-complementing rodent repair deficiency, complementation group 1 (includes overlapping antisense sequence) AAAAAAAAAA 889 469   38-1076 2.21 H. sapiens mRNA for sodium-phophate transport system 1 AAAAAAAAAA 890 469   38-1076 2.21 Homo sapiens GPI-linked anchor protein (GFRAi) mRNA, complete cds AAAAAAAAAA 891 469   38-1076 2.21 Enolase 1, (alpha) AAAAAAAAAA 892 469   38-1076 2.21 Calcium channel, voltage-dependent, P/Q type, alpha 1A subunit TGTTCCACTC 893 18  5-46 2.21 Homo sapiens CD39L2 (CD39L2) mRNA, complete cds CTCGGTGATG 894 30 10-78 2.22 H. sapiens mRNA for GTP-binding protein CTTCTCAGGG 895 17  5-43 2.22 ESTs, Highly similar to PUTATIVE CYSTEINYL-TRNA SYNTHETASE C29E6.06C [Schizosaccharomyces pombe] GGTAGCCCAC 896 18  5-40 2.22 ESTs GGGTTTTTAT 897 65   7-150 2.22 Homo sapiens dbpB-like protein mRNA, complete cds CCTGTAACCC 898 39 12-99 2.23 Human translation initiation factor elF-2alpha mRNA, 3′UTR GAAACAAGAT 899 58   5-133 2.23 Phosphoglycerate kinase 1 GATGAGTCTC 900 71  18-175 2.23 Homo sapiens proteasome subunit XAPC7 mRNA, complete cds GGCCCTAGGC 901 43   6-101 2.23 H. sapiens ERF-2 mRNA TGGCCCCACC 902 440   59-1041 2.23 Pyruvate kinase, muscle CAGCGCGCCC 903 66   5-152 2.23 ESTs AGGCGAGATC 904 91  27-231 2.24 Homo sapiens proteasome subunit XAPC7 mRNA, complete cds GCGGGGTGGA 905 64  12-155 2.24 H. sapiens ERF-1 mRNA 3′ end GGGGCCCCCT 906 21  6-54 2.24 Homo sapiens mRNA for NA14 protein AAGGAACTTG 907 24  8-61 2.24 ESTs AAGGAACTTG 908 24  8-61 2.24 Homo sapiens clone 24655 mRNA sequence AATTGCAAGC 909 18  5-47 2.24 COFILIN, NON-MUSCLE ISOFORM CCTGTGATCC 910 66  22-171 2.25 No match CCCCGCCAAG 911 66 11 2.25 Human adult heart mRNA for neutral calponin, complete cds CTCAACAGCA 912 60  12-147 2.25 Human translation initiation factor 3 47 kDa subunit mRNA, complete cds AAGGTAGCAG 913 56  17-143 2.25 ADENYLYL CYCLASE-ASSOCIATED PROTEIN 1 AAGCCAGCCC 914 78   5-180 2.25 Protein kinase C substrate 80K-H CAGCCTTGGA 915 21  5-52 2.25 ESTs, Weakly similar to siah binding protein 1 [H. sapiens] TTTGCTCTCC 916 24  8-61 2.25 Vinculin CAACATTCCT 917 41  14-106 2.26 Dopachrome tautomerase (dopachrome delta-isomerase, tyrosine-related protein 2) TACTAGTCCT 918 77  13-187 2.26 HEAT SHOCK PROTEIN HSP 90-ALPHA GACTCTGGTG 919 59   6-139 2.26 Homo sapiens chromosome 19, cosmid R29381 GACTCTGGTG 920 59   6-139 2.26 40S RIBOSOMAL PROTEIN S15A GTGGCTCACG 921 102  16-248 2.26 Homo sapiens KIAA0414 mRNA, partial cds GTGGCTCAGG 922 102  16-248 2.26 Human Tax1 binding protein mRNA, partial cds GTGGCGGGCA 923 71  16-177 2.27 H. sapiens mRNA for urea transporter GTGGCGGGCA 924 71  16-177 2.27 Homo sapiens mRNA for KIAA0472 protein, partial cds CCTGTGGTCC 925 86  18-215 2.27 No match TACAGCACGG 926 27  6-68 2.27 Homo sapiens microsomal glutathione S-transferase 3(MGST3) mRNA, complete cds GTGGCACCTG 927 20  5-51 2.27 ESTS, Highly similar to NEUROGENIC LOCUS NOTCH PROTEIN HOMOLOG PRECURSOR [Xenopus laevis] TACACGTGAG 928 40  14-103 2.27 ESTs, Weakly similar to GOLIATH PROTEIN [Drosophila melanogaster] TCAGGCATTT 929 69  24-180 2.27 ESTS, Highly similar to RAS-RELATED PROTEIN RAB-1A [H. sapiens] TTCACAAAGG 930 25  7-63 2.27 PROTEASOME ZETA CHAIN TTCTTGTGGC 931 245  54-610 2.27 Ribosomal protein S11 TCCCTATTAG 932 91  14-220 2.27 No match TACAAGAGGA 933 208  49-521 2.27 Ribosomal protein L6 TCAGACGCAG 934 344  78-862 2.28 Prothymosin alpha CAGGATCCAG 935  6-86 2.28 Human putative tumor suppressor (SNC6) mRNA, complete cds TCTGTACACC 936 55  11-135 2.28 Ribosomal protein S11 GAAGCAGGAC 937 352  54-856 2.28 COFILIN, NON-MUSCLE ISOFORM GCGCCGCCCC 938 27  5-68 2.28 ESTs, Moderately similar to nuclear autoantigen [H. sapiens] CCCTCCTGGG 939 69  23-181 2.29 ESTs TGGGCGCCTT 940 35  6-85 2.29 Uroporphyrinogen decarboxylase GTGGTACAGG 941 121  35-312 2.29 Homo sapiens microtubule-based motor (HsKIFC3) mRNA, complete cds GTGGTACAGG 942 121  35-312 2.29 ESTs GGTGAGACCT 943 93  43-255 2.29 Prostatic binding protein GAGATCCGCA 944 59  16-153 2.30 INTERFERON GAMMA UP-REGULATED I-5111 PROTEIN PRECURSOR TTGGCAGCCC 945 48   5-115 2.30 Ribosomal protein L27a GCCTTTCCCT 946 22   8-59 2.30 APOPTOSIS REGULATOR BCL-X GGAGTGGACA 947 190  29-485 2.30 60S RIBOSOMAL PROTEIN L18 TTATGGGGAG 948 29  8-74 2.30 H factor (complement)-like 1 TTATGGGGAG 949 29  6-74 2.30 TRANSFORMATION-SENSITIVE PROTEIN IEF SSP 3521 GAGTGGGGGC 950 43   9-108 2.30 ESTs, Highly similar to LYSOSOMAL PRO-X CARBOXYPEPTIDASE PRECURSOR [Homo sapiens] GTGGCACGTG 951 192  36-479 2.30 No match CTGGGCGTGT 952 126  41-331 2.31 ESTs TTGGGGTTTC 953 1243  255-3123 2.31 Ferritin heavy chain GGCTGGGCCT 954 93  14-229 2.31 Clathrin, light polypeptide (Lcb) GGCTGGGCCT 955 93  14-229 2.31 EST CCTGTTCTCC 956 28  8-73 2.31 ESTs GTGTCTCATC 957 26  6-67 2.31 ESTs GTGTCTCATC 958 26  6-67 2.31 Enolase 1, (alpha) ACGATTGATG 959 23  6-60 2.31 ESTs, Highly similar to HYPOTHETICAL 27.5 kD PROTEIN IN SPX19-GCR2 REGION [Saccharomyces cerevisiae] TTGTTGTTGA 960 75  20-194 2.31 Calmodulin 1 (phosphoylase kinase, delta) TGGCCTCCCC 961 49   9-122 2.32 H. sapiens mRNA for rho GDP-dissociation Inhibitor 1 ATCGGGCCCG 962 51  19-136 2.32 ESTs, Weakly similar to zinc finger protein [H. sapiens] GCCGCCATCA 963 45   8-111 2.33 Human protein disulfide isomerase-related protein P5 mRNA, partial cds GTGCTGGACC 964 63  15-162 2.33 Human mRNA for proteasorne activator hPA28 subunit beta, complete cds TTGTAATCGT 965 206  59-540 2.33 Human mRNA for ornithine decarboxylase antizyme, ORF 1 and ORF 2 TAATGGTAAC 966 30  5-75 2.33 Homo sapiens nuclear-encoded mitochondrial cytochrome c oxidase Va subunit mRNA, complete cds AACGACCTCG 967 156   6-369 2.33 Homo sapiens clone 24703 beta-tubulin mRNA, complete cds GCCTGCACCC 968 18  7-49 2.34 Human neuronal olfactomedin-related ER localized protein mRNA, partial cds GCCTGCACCC 969 18  7-49 2.34 ESTs AAGGTGGAGG 970 809  156-2051 2.34 60S RIBOSOMAL PROTEIN L18A AAGGAGATGG 971 467  132-1226 2.34 Ribosomal protein L31 CAGTTCTCTG 972 41   9-105 2.34 Human BTK region clone ftp-3 mRNA GTGAAACCTC 973 111  38-297 2.35 Homo sapiens intrinsic factor-B12 receptor precursor, mRNA, complete cds TAGGTTGTCT 974 546  104-1386 2.35 TRANSLATIONALLY CONTROLLED TUMOR PROTEIN CCTGTGACAG 975 61   8-150 2.35 Human mRNA for KIAA0106 gene, complete cds CTCATAAGGA 976 572  118-1463 2.35 Tag matches mitochondrial sequence GGTGGCTTTG 977 23  8-61 2.35 Homo sapiens NADH:ubiquinone oxidoreductase B12 subunit mRNA, nuclear gene encoding mitochondrial protein, complete cds GCTCAGCTGG 978 171  29-432 2.36 Eukaryotic translation elongation factor 1 delta (guanine nuclectide exchange protein) GGCCCTGAGC 979 141  14-348 2.36 Human RNA polymerase II subunit (hsRPB10) mRNA, complete cds TCTGCTAAAG 980 53   5-130 2.36 High-mobility group (nonhistone chromosomal) protein 1 TCTGCTAAAG 981 53   5-130 2.36 ESTs AGCCCCACAA 982 18  5-46 2.37 ESTs CTGAGTCTCC 983 80   9-198 2.37 Guanine nucleotide binding protein (G protein), alpha inhibiting activity polypeptide 2 TGCTTTGGGA 984 53  14-139 2.37 ESTs, Weakly similar to No definition line found [C. elegans] CCTGTCCTGC 985 60   7-149 2.37 ESTs, Moderately similar to GTP:birlding protein-associated protein [M. musculus] GGGGAAATCG 986 708   96-1772 2.37 THYMOSIN BETA-10 TCTGCCTGGG 987 48  15-130 2.37 Weakly similar to orf, len: 159, CAL 0.12 [S.cerevisiae] CAATAAACTG 988 97  12-242 2.37 PROTEIN TRANSLATION FACTOR SUI1 HOMOLOG GAGTCTGAGG 989 24  9-86 2.37 U1 snRNP 70K protein GTGGCAGGCG 990 87  16-223 2.37 Human pancreatic zymogen granule membrane protein GP-2 mRNA, complete cds GTGGCAGGCG 991 87  16-223 2.37 Nuclear factor of kappa light polypeptide gene enhancer in B-cells 2 (p49/p100) CGAGGGGCCA 992 188  33-480 2.38 Human non-muscle alpha-actinin mRNA, complete cds GTGGGGGGAG 993 19  5-49 2.38 Human DNA sequence from cosmid F0811 on chromosome 6. Contains Daxx, BING1 Tapasin, RGL2, KE2, BING4, BINGS, ESTs and CpG islands GAGTGGCTAT 994 28  8-75 2.38 Homo sapiens KIAA0419 mRNA, complete cds GAGTGGCTAT 995 28  8-75 2.38 Homo sapens mRNA for GDP dissociation inhibitor beta GTAGACTCAC 996 17  5-46 2.38 LARGE PROLINE-RICH PROTEIN BAT2 AGGGAAAGAG 997 27  7-72 2.39 Human G10 homolog (edg-2) mRNA, complete cds AGGGAAAGAG 998 27  7-72 2.39 Homo sapiens mRNA for KIAA0632 protein, partial cds CCCATCGTCC 999 3108  714-8145 2.39 Tag matches mitochondrial sequence TCGCCGCGAC 1000 34  8-90 2.40 No match TGTCCTGGTT 1001 150  39-398 2.40 CYCLIN-DEPENDENT KINASE INHIBITOR 1 CTTTTTGTGC 1002 42   6-107 2.40 Tyrosine 3-monooxygenase/tryptophan 5-monooxygenase activation protein, beta polypeptide ATAAATTGGG 1003 23  8-62 2.40 ATP synthase, H + transporting, mitochondrlal F0 complex, subunit b, isoform 1 TATCACTCTG 1004 21  8-57 2.40 Human male-enhanced antigen mRNA (Mea), complete cds GTGGTGGGCG 1005 61   9-156 2.40 No match CCACTACACT 1006 38  6-98 2.41 Human TNF-related apoptosis inducing ligand TRAIL mRNA, complete cds TGACCCCACA 1007 29 11-81 2.41 ESTs, Weakly similar to F25H5.h [C. elegans] TGATTTCACT 1008 803  132-2064 2.41 EST TGATTTCACT 1009 803  132-2064 2.41 Tag matches mitochondrial sequence GGCTCCCACT 1010 142  36-379 2.41 HEAT SHOCK PROTEIN HSP 90-BETA CCTGTGTGTG 1011 32  6-82 2.41 ESTs AATCCTGTGG 1012 514  135-1377 2.42 Ribosomal protein L8 AGGAGCAAAG 1013 43   9-112 2.42 Human mRNA for NADPH-flavin reductase complete cds CCTTTGAACA 1014 43   7-111 2.42 Human Chromosome 16 BAC clone CIT987SK-A-61E3 GTGGGGCTAG 1015 30  8-81 2.42 H. sapiens mRNA for protein phosphatase 5 AGGGTGAAAC 1016 29  5-75 2.43 Human splicing factor SRp30c mRNA, complete cds CCTCAGGATA 1017 270  72-728 2.43 ESTs CCTCAGGATA 1018 270  72-728 2.43 Tag matches mitochondrial sequence TTCCACTAAC 1019 55  12-147 2.44 Human plectin (PLEC1) mRNA, complete cds CCCCCGTGAA 1020 86  16-228 2.44 Homo sapiens interleukin-1 receptor-associated kinase (IRAK) mRNA, complete cds TGTGCTCGGG 1021 107  35-295 2.44 Human mRNA for KIAA0088 gene, partial cds AAGCCTTGCT 1022 20  6-54 2.44 ESTs TGTTCATCAT 1023 40  15-114 2.45 ESTs, Weakly similar to neuroendocrine-specific protein C [H. sapiens] AACTAACAAA 1024 86  24-234 2.45 Ubiquitin A-52 residue ribosomal protein fusion product 1 GCTGTTGCGC 1025 158  33-419 2.45 40S RIBOSOMAL PROTEIN S20 GGATGTGAAA 1026 45   7-118 2.45 Antigen identified by monoclonal antibodies 12E7, F21 and O13 ACTGGTACGT 1027 34  8-90 2.45 Homo sapiens F1Fo-ATPase synthase f subunit RNA, complete cds TTGTATTCCA 1028 16  5-45 2.45 H. sapiens mRNA for alpha 4 protein GGCTGGGGGC 1029 437   48-1124 2.46 Human profilin mRNA, complete cds CCACTGCACT 1030 925  181-2460 2.47 Thyroid autoantigen 70 kD (Ku antigen) CCACTGCACT 1031 925  181-2460 2.47 Enhancer of zeste (Drosophila) homolog 1 CCACTGCACT 1032 925  181-2460 2.47 CD19 antigen CCACTGCACT 1033 925  181-2460 2.47 Human clone 23732 mRNA, partial cds CCACTGCACT 1034 925  181-2460 2.47 Annexin II (lipocortin II) CCACTGCACT 1035 925  181-2460 2.47 Alkaline phosphatase, plaental (Regan isozyme) CCACTGCACT 1036 925  181-2460 2.47 Homo sapiens clone 24760 mRNA sequence CCACTGCACT 1037 925  181-2460 2.47 Homo sapiens carbonic anhydrase precursor (CA 12) mRNA, complete cds CCACTGCACT 1038 925  181-2460 2.47 Homo sapiens methyl-CpG binding protein MBD4 (MBD4) mRNA, complete cds CCACTGCACT 1039 925  181-2460 2.47 Phosphodiesterase 4C, cAMP-specific (dunce (Drosophila)-homolog phosphodiesterase E1) CCACTGCACT 1040 925  181-2460 2.47 Human SNRPN mRNA, 3′ UTR, partial sequence CCACTGCACT 1041 925  181-2460 2.47 Homo sapiens brachyury variant A (TBX1) mRNA, complete cds CCACTGCACT 1042 925  181-2460 2.47 H. sapiens beta glucuronidase pseudogene CCACTGCACT 1043 925  181-2460 2.47 G PROTEIN-ACTIVATED INWARD RECTIFIER POTASSIUM CHANNEL 4 CACTTGCCCT 1044 109  21-290 2.47 ESTs, Highly similar to ACETYL-COENZYME A SYNTHETASE [Escherichia coli] CACTTGCCCT 1045 109  21-290 2.47 ESTs, Highly similar to NADH-UBIQUINONE OXIDOREDUCTASE B22 SUBUNIT [Bos taurus] GCAAGCCAAC 1046 100  17-264 2.47 Tag matches mitochondrial sequence TAGATAATGG 1047 49   5-126 2.47 Homo sapiens clone 24703 beta-tubulin mRNA, complete cds TCGAAGCCCC 1048 251  60-682 2.47 Tag matches mitochondrial sequence AGAAAAAAAA 1049 115   9-294 2.48 Enolase 1, (alpha) AGAAAAAAAA 1050 115   9-294 2.48 Human mRNA for KIAA0099 gene, complete cds GGCGCCTCCT 1051 66   9-172 2.48 Eukaryotic translation initiation factor 4A (eIF-4A) isoform 1 GGCGCCTCCT 1052 66   9-172 2.48 TRANSALDOLASE TAAACTGTTT 1053 29  7-79 2.48 ESTs TAAACTGTTT 1054 29  7-79 2.48 40S RIBOSOMAL PROTEIN S14 GGCCTTTTTT 1055 36  6-95 2.48 Human mRNA for histone H1x, complete cds GGCCTTTTTT 1056 36  6-95 2.48 Homo sapiens mRNA for KIAA0529 protein, partial cds GCGACAGCTC 1057 44   5-115 2.48 60S RIBOSOMAL PROTEIN L24 CCCACACTAC 1058 57  17-159 2.49 Human signal-transducing guanine nucleotide-binding regulatory (G) protein beta subunit mRNA, complete cds AGCAGATCAG 1059 390   65-1034 2.49 S100 calcium-binding protein A10 (annexin II ligand, calpactin I, light polypeptide (p11) GCATAGGCTG 1060 90  15-240 2.49 ELONGATION FACTOR TU, MITOCHONDRIAL PRECURSOR GAGGCCGACC 1061 25  9-72 2.49 Basigin AAATGCCACA 1062 42   6-110 2.49 ESTs, Weakly similar to neuroendocrine-specific protein C [H. sapiens] AGCCCTACAA 1063 754  208-2089 2.49 Tag matches mitochondrial sequence TTGGTGAAGG 1064 399   57-1053 2.50 Human thymosin beta-4 mRNA, complete cds CCGGGCCCAG 1065 46   9-125 2.50 Homo sapiens mRNA for TRIP6 thyroid receptor interacting protein) TTCATACACC 1066 772  125-2055 2.50 Tag matches mitochondrial sequence GCAGCCATCC 1067 790   96-2072 2.50 Ribosomal protein L28 GCCGGGTGGG 1068 668  126-1796 2.50 Basigin GCTCCCAGAC 1069 53   9-142 2.50 Homo sapiens mRNA for synaptogyrin 2 AGCCACCGTG 1070 39   8-105 2.51 No match TCAGCTGGCC 1071 16  6-47 2.51 Human nuclear factor NF9O mRNA, complete cds GGGGGCGCCT 1072 22  6-62 2.52 Adenine nucleotide transiocator 3 (liver) CGGCCCAACG 1073 59  14-161 2.52 H. sapiens mRNA for arginine methyltransferase, splice variant, 1262 bp TGGCCATCTG 1074 65  14-177 2.52 ESTs, Weakly similar to N-methyi-D-aspartate receptor glutamate-binding chain [R. norvegicus] CCTCCCCCGT 1075 59  11-159 2.52 Homo sapiens breakpoint cluster region protein 1 (BCRG1) mRNA, complete cds ACTTGTTCGC 1076 27  6-73 2.52 ESTs AAGACTGGCT 1077 30  6-81 2.52 ESTs, Highly similar to Surf-4 protein [M. musculus] AGCACATTTG 1078 42   5-112 2.53 ESTs, Highly similar to deduced protein product shows significant homology to coactosin from Dictyostelium discoideum [H. sapiens] GTGAAGGCAG 1079 467   83-1265 2.53 Ribosomal protein S3A CAATAAATGT 1080 227  43-620 2.54 Ribosomal protein L37 GCCAGGGCGG 1081 46   5-121 2.54 ESTs, Highly similar to HYPOTHETICAL 52.8 KD PROTEIN TO5E11.51N CHROMOSOME IV [Caenorhabditis elegans] GTGTAATAAG 1082 57   9-154 2.54 Heterogeneous nuclear ribonucleoprotein A2/B1 TTCTGCACTG 1083 25  6-70 2.54 Collagen, type I, alpha-2 TTCTGCACTG 1084 25  6-70 2.54 ESTs GTGAAACCCC 1085 1352  514-3963 2.55 Myelin oligodendrocyte glycoprotein (alternative products) GTGAAACCCC 1086 1352  514-3963 2.55 Dihydrolipoamide branched chain transacylase (E2 component of branched chain keto acid dehydrogenase complex) GTGAAACCCC 1087 1352  514-3963 2.55 Human mRNA for platelet-activating factor acetylhydrolase 2, complete cds GTGAAACCCC 1088 1352  514-3963 2.55 GRANULOCYTE-MACROP HAGE COLONY-STIMULATING FACTOR RECEPTOR ALPHA CHAIN PRECURSOR GTGAAACCCC 1089 1352  514-3963 2.55 Thymopoietin GTGAAACCCC 1090 1352  514-3963 2.55 Basic fibroblast growth factor (bFGF) receptor (shorter form) GTGAAACCCC 1091 1352  514-3963 2.55 Homo sapiens mRNA for KIAA0794 protein, partial cds GTGAAACCCC 1092 1352  514-3963 2.55 Homo sapiens RNA polymerase I subunit hRPA39 mRNA, complete cds GTGAAACCCC 1093 1352  514-3963 2.55 Homo sapiens mRNA for KIAA0701 protein, partial cds GTGAAACCCC 1094 1352  514-3963 2.55 Homo sapiens mRNA for MAX.3 cell surface antigen GTGAAACCCC 1095 1352  514-3963 2.55 Homo sapiens mRNA for KIAA0706 protein, complete cds GTGAAACCCC 1096 1352  514-3963 2.55 Homo sapiens deoxyribonuclease II mRNA, complete cds GTGAAACCCC 1097 1352  514-3963 2.55 Homo sapiens clone 24758 mRNA sequence GTGAAACCCC 1098 1352  514-3983 2.55 Kangai 1 (suppression of tumorigenicity 6, prostate; CD82 antigen (R2 leukocyte antigen, antigen detected by monoclonal and antibody IA4)) GTGAAACCCC 1099 1352  514-3963 2.55 Leplin (murine obesity homolog) GACACCTCCT 1100 45   7-122 2.55 ESTs, Weakly similar to TIP49 [R.norvegicus] GACGTGTGGG 1101 94   6-247 2.56 H2AZ histone GCAAAACCCC 1102 162  46-461 2.56 Homo sapiens tumor necrosis factor superfamily member LIGHT mRNA, complete cds TACCAGTGTA 1103 46   6-124 2.56 Heat shock 60 kD protein I (chaperonin) CCCCTCCCCA 1104 30 11-90 2.58 Chromosome 22q13 BAC Clone CIT987SK-384D8 complete sequence GGTGATGAGG 1105 35  8-98 2.58 Homo sapiens BC-2protein mRNA, complete cds GTGTGTAAAA 1106 27  6-76 2.59 Homo sapiens CDM mRNA GGCTCCTCGA 1107 41  11-117 2.59 Homo sapiens tapasin (NGS-17) mRNA compiete cds AAAAGAAACT 1108 62  12-174 2.60 POLYADENYLATE-BINDING PROTEIN CAGCGCACAG 1109 22  6-64 2.60 ESTs CTGGGAGAGG 1110 35  11-102 2.60 ESTs GAAAAATGGT 1111 340  58-943 2.60 Laminin receptor (2H5 epitope) ATCACGCCCT 1112 192  26-527 2.61 Tag matches mitochondrial sequence TAGCTCTATG 1113 107  43-323 2.61 ATPase, Na + /K + transporting, alpha 1 polypeptide GTATTGGCCT 1114 21  7-61 2.61 Human p76 mRNA, complete cds CCCGACGTGC 1115 56  20-171 2.62 ESTs, Highly similar to NADH-UBIQUINONE OXIDOREDUCTASE B9 SUBUNIT [Bos taurus] GAAGTTATGA 1116 32  7-89 2.62 T-COMPLEX PROTEIN 1, ALPHA SUBUNIT TAAAAAAAAA 1117 108   7-290 2.63 ESTs TAAAAAAAAA 1118 108   7-290 2.63 Ubiquitin-conjugating enzyme E2A (RAD6 homolog) TAAAAAAAAA 1119 108   7-290 2.63 Homo sapiens protein kinase (BUB1) mRNA, complete cds GCCGCCCTGC 1120 71  13-199 2.63 Acyl Coenzyme A dehydrogenase, very long chain TTTGGGGCTG 1121 78  30-234 2.63 Human mRNA for proton-ATPase-like protein, complete cds GTGGCAGGCA 1122 86  18-245 2.63 No match GGCTGTACCC 1123 79  18-225 2.63 CYSTEINE-RICH PROTEIN AGCAGGGCTC 1124 128  17-353 2.63 ESTs, Highly similar to PNG gene [H. sapiens] AAGAAGATAG 1125 152  10-412 2.64 60S RIBOSOMAL PROTEIN L23A TCTGGGGACG 1126 27  7-76 2.64 Human translational initiation factor 2 beta subunit (eIF-2-beta) mRNA, complete cds GCTAGGTTTA 1127 80   9-220 2.65 Tag matches mitochondrial sequence TGGTGACAGT 1128 32  6-91 2.65 Homo sapiens histone H2A.F/Z variant (H2AV) mRNA, complete cds TTACCATATC 1129 196  46-566 2.65 Human mRNA for ribosomal protein L39, complete cds GTGGCGGGTG 1130 59   9-165 2.65 No match TGGATCCTAG 1131 28  7-81 2.66 Homo sapiens NADH:ubiqulnone oxidoreductase NDUFS3 subunit mRNA, nuclear gene encoding mitochondrial protein, complete cds GGGTTTGAAC 1132 22  7-64 2.66 Homo sapiens SKB1Hs mRNA, complete cds AATGCAGGCA 1133 83   9-231 2.67 S-adenosylhomocysteine hydrolase ACATCGTAGG 1134 30 10-90 2.67 ESTS AACGCTGCCT 1135 59  10-167 2.67 Human APRT gene for adenine phosphoribosyltransferase TGGAGGTGGG 1136 20  6-58 2.68 ESTs TGCCTGCTCC 1137 21  8-84 2.68 ESTs CTTCCAGCTA 1138 358   87-1050 2.69 Annexin II (lipocortin II) GTAAGTGTAC 1139 80   8-223 2.69 ESTs GTAAGTGTAC 1140 80   8-223 2.69 Tag matches mitochondrial sequence GTGTCTCGCA 1141 40   6-112 2.70 Annexin XI (56 kD autoantigen) ATCCGGCGCC 1142 114  14-321 2.70 Homo sapiens RNA polymerase II transcription factor SIII p18 subunit mRNA, complete cds TGCCTGCACC 1143 232  61-688 2.70 Cystatin C (arnyloid angiopathy and cerebral hemorrhage) TTCCTATTAA 1144 42   7-121 2.72 ESTs CAGGAGTTCA 1145 91  23-270 2.72 Homo sapiens Arp2/3 protein complex subunit p34-Arc (ARC34) mRNA, complete cds GTCTGCGTGC 1146 51   5-143 2.72 Proteasome component C2 GAAATACAGT 1147 264  50-769 2.72 ESTs GAAATACAGT 1148 264  50-769 2.72 Cathepsin D (lysosomal aspartyl protease) TGAGCCCGGC 1149 38   8-106 2.74 ESTs, Highly similar to LATENT TRANSFORMING GROWTH FACTOR BETA BINDING PROTEIN 1 PRECURSOR [Rattus norvegicus] GTGGTGTGTG 1150 48   6-134 2.74 Homo sapiens NF-AT4c mRNA, complete cds GTGGTGTGTG 1151 46   6-134 2.74 Acid phosphatase, prostate TCACCCACAC 1152 383  111-1167 2.76 Ribosomal protein L17 TCACCCACAC 1153 383  111-1167 2.76 ESTs, Weakly similar to !!!! ALU SUBFAMILY J WARNING ENTRY !!!! [H. sapiens] CTGGATCTGG 1154 65  12-190 2.76 Glycogen phosphorylase (brain form) GAAGATGTGT 1155 95  24-287 2.77 ESTs, Highly similar to HYPOTHETICAL 6.3 KD PROTEIN ZK652.2 IN CHROMOSOME II [Caenorhabditis elegans] CGGATAACCA 1156 53   6-153 2.78 Human cell cycle protein p38-2G4 homolog (hG4.1) mRNA, compete cds TCAGAAGGTG 1157 38   5-111 2.78 ESTs, Weakly similar to RNA-binding protein [H. sapiens] GAGAAACCCC 1158 95  22-288 2.78 Human mRNA for KIAA0134 gene, complete cds GAGAAACCCC 1159 95  22-288 2.78 H. sapiens F11 mRNA GAGAAACCCC 1160 95  22-288 2.78 Human mRNA for KIAA0159 gene, complete cds CTCGTTAAGA 1161 32  6-95 2.80 Human calmodulin mRNA, complete cds TTGGAGATCT 1162 93  20-279 2.80 Human NADH:ubiquinone oxidoreductase MLRQ subunit mRNA, complete cds GAGGTCCCTG 1163 65  12-193 2.81 PROTEASOME IOTA CHAIN TTCCGCGTGC 1164 50   5-146 2.81 Homo sapiens lysyl hydroxylase isoform 3 (PLOD3) mRNA complete cds CAGCCCAACC 1165 64   8-187 2.81 Homo sapiens eukaryotic translation initiation factor 3 subunit (p42) mRNA, complete cds GTGGCTCACA 1166 104   9-303 2.81 Adenosine A2b receptor TAGAAAGGCA 1167 31  6-92 2.82 H. sapiens ERF-2 mRNA TAAGTAGCAA 1168 33   7-102 2.83 ESTS, Weakly similar to putative [M. musculus] GGTGAGACAC 1169 128  25-389 2.83 Adenine nucleotide translocator 3 (liver) CCCATCGTCT 1170 39   5-116 2.83 No match CCGATCACCG 1171 59  14-182 2.83 Human translational initiation factor 2 beta subunit (eIF-2-beta) mRNA, complete cds GAATCGGTTA 1172 43  10-133 2.83 Homo sapiens NADH-ubiquinone oxidoreductase 15 kDa subunit mRNA, complete eds AACCCAGGAG 1173 110  11-323 2.84 No match TTTTGAAGCA 1174 33  15-108 2.85 Homo sapiens hepatitis B virus X interacting protein (XIP) mRNA, complete cds CACAGGCAAA 1175 40   8-122 2.85 Human mRNA for KIAA0005 gene, complete cds TCAGCTTCAC 1176 30  7-93 2.85 Human mRNA for KIAA0359 gene, complete cds TCAGCTTCAC 1177 30  7-93 2.85 Human putative G-protein (GP-1) mRNA, complete cds GAGGGCCGGT 1178 61  10-185 2.85 ESTs, Highly similar to HISTONE H2A [Cainina moschata] CCCCAGCCAG 1179 320  74-988 2.86 Ribosomal protein S3 GTGGTGGGTG 1180 59   5-176 2.86 Human RACH1 (RACH1) mRNA, complete cds CTGCCAAGTT 1181 100  27-314 2.87 Homo sapiens mRNA for zyxin GAGAAACCCT 1182 46  12-144 2.87 Homo sapiens mRNA, chromosome 1 specific transcript KIAA0506 GAGAAACCCT 1183 46  12-144 2.87 Vitamin D (1,25-dihydroxyvitamin D3) receptor ACTAACACCC 1184 544  132-1694 2.87 Tag matches mitochondrial sequence TTTTGGGGGC 1185 37   7-112 2.88 ESTs TTTTGGGGGC 1186 37   7-112 2.88 Human mRNA for proton-ATPase-like protein, complete cds GTGAAACCCA 1187 43  15-140 2.88 No match GCTTTCATTG 1188 27 12-89 2.89 Homo sapiens clone 23967 unknown mRNA, partial cds GTGGCACGCA 1189 33   6-101 2.89 No match GGGTCAAAAG 1190 52  14-165 2.89 HISTONE H3.3 GGGGGTCACC 1191 81   9-186 2.90 ATP SYNTHASE LIPID-BIND ING PROTEIN P1 PRECURSOR GTGAAACCCT 1192 664  198-2130 2.91 Carboxypeptidase M GTGAAACCCT 1193 664  198-2130 2.91 H. sapiens mRNA for laminin GTGAAACCCT 1194 664  198-2130 2.91 GC-RICH SEQUENCE DNA-BINDING FACTOR GTGAAACCCT 1195 664  198-2130 2.91 Homo sapiens mRNA for KIAA0596 protein, partial cds GTGAAACCCT 1196 664  198-2130 2.91 Homo sapiens clone 23605 mRNA sequence GTGAAACCCT 1197 664  198-2130 2.91 Formyl peptide receptor 1 AGTTGAAATT 1198 20  6-64 2.91 ESTs AGAATCGCTT 1199 74  11-228 2.92 Homo sapiens coatomer protein (COPA) mRNA, complete cds AGGTCAAGAG 1200 20  7-65 2.92 No match CTAACCAGAC 1201 43  11-136 2.93 ANGIOTENSIN-CONVERTING ENZYME PRECURSOR, SOMATIC GGGATGGCAG 1202 38   5-115 2.93 VALYL-TRNA SYNTHETASE AGACCCACAA 1203 162  39-512 2.93 Tag matches mitochondrial sequence TCGAAGAACC 1204 50   7-155 2.94 CD63 antigen (melanoma 1 antigen) TGAAATAAAA 1205 71   6-214 2.95 Nucleophosmin (nucleolar phosphoprotein B23, numatrin) ACTGAGGTGC 1206 34   9-109 2.95 Homo sapiens FGF-1 intracellular binding protein (FIBP) mRNA, complete cds ACTCAGAAGA 1207 50  12-180 2.95 ESTs, Highly similar to NADH-UBIQUINONE OXIDOREDUCTASE AGGG SUBUNIT PRECURSOR [Bos taurus] GAACACATCC 1208 440  113-1414 2.96 Ribosomal protein L19 AACTAATACT 1209 67   6-203 2.96 ESTs, Weakly similar to !!!! ALU SUBFAMILY WARNING ENTRY !!!! H. sapiens] AGATGTGTGG 1210 30  8-98 2.96 Hydroxyacyl-Coenzyme A dehydrogenase/3-ketoacyl-Coenzyme A thiolase/enoyl-Coenzyme A hydratase (trifunctiona/protein), beta subunit GTGGTGTGCA 1211 27  8-89 2.97 Homo sapiens RNA transcript from U17 small nucleolar RNA host gene, variant U17HG-AB GGCGTCCTGG 1212 55   9-172 2.98 ESTs, Weakly simiiar to No definition line found [C. elegans] CCTGCAATCC 1213 47  11-152 2.98 No match GCCTGGCCAT 1214 57  14-184 2.99 GUANINE NUCLEOTIDE-BINDING PROTEIN BETA SUBUNIT-LIKE PROTEIN 12.3 - GCCTGGCCAT 1215 57  14-184 2.99 ESTs, Moderately similar to SULFATED SURFACE GLYCOPROTEIN 185 [Volvox carteri] GCTGCCCTTG 1216 134  14-415 2.99 Human alpha-tubulin mRNA, 3′ end GCTGCCCTTG 1217 134  14-415 2.99 Human alpha-tubulin mRNA, complete cds GCCAGCCCAG 1218 90  12-281 3.00 Human transcriptional corepressor hKAP1/TIF1B mRNA, complete cds TCCTATTAAG 1219 160  34-515 3.00 ESTs ATTGTGCCAC 1220 34   8-110 3.00 No match CCATTGCACT 1221 237  58-773 3.02 Ataxia telangiectasia mutated (includes complementation groups A,C and D) GCACCTCAGC 1222 38   8-122 3.02 ESTs TTGGTCAGGC 1223 129  24-419 3.05 Calcium modulating ligand TTGGTCAGGC 1224 129  24-419 3.05 Human melanoma antigen recognized by T-cells (MART-1) mRNA GGGCCCCGCA 1225 30  6-98 3.05 Human mRNA for KIAA0123 gene, partial cds GTGGCACACA 1226 70  15-228 3.06 Homo sapiens AIBC1 (AIBC1) mRNA, complete cds GTGGCACACA 1227 70  15-228 3.06 Homo sapiens mRNA for MEGF8, partial cds TTGGCCAGGC 1228 346   87-1149 3.07 Human cytochrome P450-IIB (hIIB3) mRNA, complete cds TTGGCCAGGC 1229 346   87-1149 3.07 Homo sapiens X-ray repair cross-complementing protein 2 (XRCC2) mRNA, complete cds TTGGCCAGGC 1230 346   87-1149 3.07 Homo sapiens oligodendrocyte-specific protein (OSP) mRNA, complete cds TTGGCCAGGC 1231 346   87-1149 3.07 MHC class II transactivator TTGGCCAGGC 1232 346   87-1149 3.07 Fc fragment of IgA, receptor for TTGGCCAGGC 1233 346   87-1149 3.07 Protein kinase, interferon-inducible double stranded RNA dependent TTGGCCAGGC 1234 346   87-1149 3.07 Zinc flnger protein 157 (HZF22) GTCACTGCCT 1235 20  5-68 3.08 Homo sapiens mRNA for Ribosomal protein kinase B (RSK-B) GCCACCCCGT 1236 61   8-197 3.09 Glucose-6-phosphate dehydrogenase TCCCTATAAG 1237 107  17-347 3.09 No match CCTGTAATCC 1238 1302  453-4484 3.10 Breast cancer 2, early onset CCTGTAATCC 1239 1302  463-4484 3.10 Integrin, beta 3 (platelet glycoprotein IIIa, antigen CD61) CCTGTAATCC 1240 1302  453-4484 3.10 Transcription factor 1, hepatic; LF-B1, hepatic nuclear factor (HNF1), albumin proximal factor CCTGTAATCC 1241 1302  453-4484 3.10 Homo sapiens interferon induced tetratricopeptide protein IF160 (IFIT4) mRNA, complete cds CCTGTAATCC 1242 1302  453-4484 3.10 H. sapiensRBQ-3 mRNA CCTGTAATCC 1243 1302  453-4484 3.10 Human hVps41p (HVPS41) mRNA, complete cds CCTGTAATCC 1244 1302  453-4484 3.10 Human TNF-alpha converting enzyme precursor, mRNA, alternatively spliced, complete cds CCTGTAATCC 1245 1302  463-4484 3.10 Homo sapiens mRNA for KIAA0526 protein, complete cds CCTGTAATCC 1246 1302  453-4484 3.10 Homo sapiens melastatin 1 (MLSN1) mRNA, complete cds CCTGTAATCC 1247 1302  453-4484 3.10 Homo sapiens clone 23716 mRNA sequence CCTGTAATCC 1248 1302  453-4484 3.10 Homo sapiens mRNA for KIAA0538 protein, partial cds CCTGTAATCC 1249 1302  453-4484 3.10 HLA CLASS I HISTOCOMPATIBILITY ANTIGEN, E E*0101/E*0102 ALPHA CHAIN PRECURSOR CCTGTAATCC 1250 1302  453-1484 3.10 Homo sapiens decoy receptor 2 mRNA, complete cds CCTGTAATCC 1251 1302  453-4484 3.10 CATHEPSIN S PRECURSOR CCTGTAATCC 1252 1302  453-4484 3.10 Homo sapiens type 6 nucleoside diphosphate kinase NM23-H6 (NM23-H6) mRNA, complete cds CCTGTAATCC 1253 1302  453-4484 3.10 5′ nucleotidase (CD73) CCTGTAATCC 1254 1302  453-4484 3.10 Homo sapiens mRNA, chromosome I specific transcript KIA0508 CCTGTAATCC 1255 1302  453-4484 3.10 H. sapiens mRNA for p85 beta subunit of phosphatidyl-inositol-3-kinase CCTGTAATCC 1256 1302  453-4484 3.10 Interleukin 12 receptor, beta-2 TCCCCGTACA 1257 3918   290-12438 3.10 No match GTCACACCAC 1258 30   9-104 3.11 ESTs GTCACACCAC 1259 30   9-104 3.11 Prothymosin alpha ATGGCAAGGG 1260 56   9-182 3.11 ESTs, Weakly similar to !!!! ALU SUBFAMILY J WARNING ENTRY !!!! [h.sapiens] CTGTTGGCAT 1261 111  27-372 3.11 Ribosomal protein L21 CTAGCCTCAC 1262 623  181-2105 3.12 Actin, gamma 1 AGTGCAAGAC 1263 57  10-187 3.12 Tag matches mitochondrial sequence CCTGTAGTCC 1264 231  67-791 3.13 No match TTTTCTGAAA 1265 66  12-218 3.13 Thioredoxin CTCCCCTGCC 1266 62   9-203 3.14 Capping protein (actin filament), gelsolin-like TCTCTTTTTC 1267 32   8-108 3.14 H. sapiens tissue specific mRNA GCGGACGAGG 1268 35   8-118 3.14 Homo sapiens TFAR19 mRNA, complete cds GCGGACGAGG 1269 35   8-118 3.14 Human tip associatIng protein (TAP) mRNA, complete cds GGAGTCATTG 1270 56  12-190 3.16 Human mRNA for proteasome subunit HsC10-II, complete cds GTAGCAGGTG 1271 67  21-233 3.17 Homo sapiens cargo selection protein TIP47 (TIP47) mRNA, complete cds CGCAAGCTGG 1272 65  13-221 3.17 LAMIN A GTGAAACCCG 1273 38  11-126 3.18 No match AGGTCAGGAG 1274 359  133-1274 3.18 Major histocompatibility complex, class II, DR beta 5 AGGTCAGGAG 1275 359  133-1274 3.18 Human mRNA for KIAA0331 gene, complete cds AGGTCAGGAG 1276 359  133-1274 3.18 Human mRNA for KIAA0226 gene, complete cds GAATGCAGTT 1277 13  5-45 3.18 ESTs GAATGCAGTT 1278 13  5-45 3.18 ESTs GAATGCAGTT 1279 13  5-45 3.18 ESTs GTGAGCCCAT 1280 77  21-269 3.21 HEAT SHOCK PROTEIN HSP 90-BETA GTAATCCTGC 1281 109  23-375 3.22 Tag matches ribosomal RNA sequence TGAAGTAACA 1282 31   7-108 3.22 PROTEIN TRANSLATION FACTOR SUI1 HOMOLOG TGCCTGTAAT 1283 59  15-206 3.22 ISLET AMYLOID POLYP EPTIDE PRECURSOR GTAGCATAAA 1284 28  6-95 3.23 Human ubiquitin gene, complete cds CCGTGGTCGT 1285 67   9-224 3.23 Fibrillarin ATGAAACCCC 1286 67  24-240 3.23 Homo sapiens mRNA expressed in osteoblast, complete cds AAGATTGGTG 1287 81  13-275 3.25 CD9 antigen ATCCGTGCCC 1288 35  11-124 3.25 Human calmodulin mRNA, complete cds CCCTTCACTG 1289 16  5-58 3.26 ESTs, Moderately similar to !!!! ALU SUBFAMILY J WARNING ENTRY !!!! H. sapiens] CCCTTCACTG 1290 16  5-58 3.26 ESTs CAGCTGGGGC 1291 54   6-183 3.26 Polypyrimidine tract binding protein (hnRNP I) {alternative products} CAGGCCCCAC 1292 109  17-370 3.26 Human mRNA for calglzzarin, complete cds TGTTTATCCT 1293 25  7-89 3.26 · TAACCAATCA 1294 52  14-184 3.26 Human Rab5c-like protein mRNA, complete cds CACCTGTAGT 1295 32   5-110 3.27 Ribosomal protein L5 TACCCTAAAA 1296 103  16-351 3.27 Human kpni repeat mma (cdna clone pcd-kpni-4), 3′ end TACCCTAAAA 1297 103  16-351 3.27 Homo sapiens mRNA for KIAA0675 protein complete cds TACCCTAAAA 1298 103  16-351 3.27 Human Line-1 repeat mRNA with 2 open reading frames TGCCTCTGCG 1299 175  83-655 3.28 Human platelet-endothelial tetraspan antigen 3 mRNA, complete cds GCAAAACCCT 1300 81  19-284 3.28 No match AAGGACCTTT 1301 115  18-396 3.28 ESTs CTGGCGCCGA 1302 39   9-138 3.30 ESTs, Weakly similar to F35G12.9 [C. elegans] GAAGCTTTGC 1303 133  15-454 3.30 HEAT SHOCK PROTEIN HSP 90-ALPHA GCTCCGAGCG 1304 57   6-195 3.30 Ribosomal protein S16 TTGCCCAGGC 1305 59  21-251 3.30 Cell division cycle 42 (GTP-binding protein, 25 kD) TTGCCCAGGC 1306 69  21-251 3.30 Human brain mRNA hoMOLOGOUS to 3′UTR of human CD24 gene, partial sequence ACCCACGTCA 1307 55   9-189 3.31 Jun B proto-oncogene GCTCCACTGG 1308 29   8-103 3.31 Mannose-6-Phosphate receptor (cation dependent) TTTAACGGCC 1309 142  18-489 3.31 Tag matches mitochondrial sequence CTTGTAATCC 1310 71  11-248 3.32 ESTs, Moderately similar to !!!! ALU SUBFAMILY J WARNING ENTRY !!!! [H. sapiens] CACTTTTGGG 1311 47   8-165 3.33 ESTs CCGGGTGATG 1312 92  20-325 3.33 Human copper transport protein HAH1 (HAH1)mRNA, complete cds GGGGTAAGAA 1313 62   8-213 3.33 Prostatic binding protein TGACTGGCAG 1314 49   7-172 3.34 CD59 antigen p18-20 (antigen identified by monoclonal antibodies 16.3A5, EJ16, EJ30, EL32 and G344) CAATGTGTTA 1315 47  17-176 3.39 H. sapiens mRNA for NADH dehydrogenase GGCTCGGGAT 1316 74   6-257 3.40 CALPAIN 1, LARGE TGCCTGTAGT 1317 71  15-258 3.40 Hum ORF (CE15) mRNA, 3′ flank CGCCGCCGGC 1318 807  148-2906 3.42 Human ribosomal protein L35 mRNA, complete cds GGTGGGGAGA 1319 68   6-239 3.44 Human chromosome 17q21 mRNA clone LF113 GTAAAACCCT 1320 24  8-90 3.44 No match GGCTCCTGGC 1321 100   9-354 3.44 Homo sapiens b(2)gcn homolog mRNA, complete cds AGTAGGTGGC 1322 53   5-188 3.46 Tag matches mitochondrial sequence GGAGGTGGGG 1323 126  19-456 3.48 Granulin CCTTTGGCTA 1324 27   5-100 3.49 ESTs, Highly similar to 40S RIBOSOMAL PROTEIN S27 [i Rattus norvegicus] AGAAAGATGT 1325 74  11-268 3.50 Annexin I (lipocortin I) AGAACAAAAC 1326 75   6-271 3.52 Proliferation-associated gene A (natural killer-enhancing factor A) AACTAAAAAA 1327 110   9-396 3.53 Ubiquitin A-52 residue ribosomal protein fusion product 1 ATTGCACCAC 1328 38   5-138 3.53 Human transglutaminase mRNA, 3′ untranslated region GATCCCAACT 1329 389   27-1402 3.54 H. sapiens mRNA for metallothionein isoform 2 GATCCCAACT 1330 389   27-1402 3.54 Human mRNA for metallothionein from cadmium-treated cells CACTACTCAC 1331 358   99-1361 3.54 Tag matches mitochondrial sequence CTGTACAGAC 1332 132  20-487 3.55 Homo sapiens beta 2 gene TACCCTAGAA 1333 43  5-159 3.58 Estrogen receptor GTAAAACCCC 1334 57   8-213 3.58 Tumor necrosis factor receptor 2 (75 kD) GTAAAACCCC 1335 57   8-213 3.58 Homo sapiens mRNA for KIAA0632 protein, partial cds GTAAAACCCC 1336 57   8-213 3.58 Homo sapines protease-activated receptor 4 mRNA, complete cds CTGAGAGCTG 1337 32   9-125 3.61 Homo sapiens growth-arrest-specific protein (gas) mRNA, complete cds GGCTGGTCTG 1338 57   6-211 3.62 ESTs ACGCAGGGAG 1339 360   29-1334 3.63 HEAT SHOCK PROTEIN HSP 90-ALPHA GCCCTCGGCC 1340 44   5-165 3.63 Homo sapiens mRNA for protein phosphatase 20 gamma CTCCCTTGCC 1341 20  5-78 3.64 ESTs, Hi~hIy similar to COATOMER ZETA SUBUNIT [Bos taurus] CCTGTAATCT 1342 81  27-323 3.65 V-erb-b2 avian erythroblastic leukemia viral oncogene homolog 3 {alternative products} AGGTCCTAGC 1343 391   16-1448 3.66 Glutathione-S-transferase pi-1 ACTGAAGGCG 1344 68  15-266 3.68 Human metargidin precursor mRNA, complete cds AAGGAAGATG 1345 24  6-94 3.68 PROTEASOME COMPONENT C13 PRECURSOR CCGACGGGCG 1346 60  14-237 3.71 Tag matches ribosomal RNA sequence GCCCCCAATA 1347 428    6-1601 3.73 Lectin, galactoside-binding, soluble, 1 (galectin 1) AGGATGTGGG 1348 49   9-193 3.74 Homo sapiens mRNA for KIAA0706 protein, complete cds GGAGGCCGAG 1349 26   5-103 3.75 ESTs, Weakly similar to allograft inflammatory factor-1 [H. sapiens] ACCCCCCCGC 1350 65   6-251 3.76 Jun proto-oncogene CTGGCCTGTG 1351 30   6-120 3.80 Homo sapiens mRNA for CIRP, complete cds CTGGCCTGTG 1352 30   6-120 3.80 Villin 2 (ezrin) CTGGCCTGTG 1353 30   6-120 3.80 Homo sapiens clone 23565 unknown mRNA, partial cds CACCCCCAGG 1354 29   7-118 3.80 ESTs CACCCCCAGG 1355 29   7-118 3.80 Human Gps2 (GPS2) mRNA, complete cds GTGAAACTCC 1356 66  16-269 3.81 Human 53K isoform of Type II phosphatidylinositol-4-phosphate 5-kinase (PIPk) mRNA, complete cds GTGAAACTCC 1357 66  16-269 3.81 Human mRNA for KIAA0328 gene, partial cds AGAATTGCTT 1358 50  12-201 3.81 Homo sapiens nephrin (NPHS1) mRNA, complete cds AGAATTGCTT 1359 50  12-201 3.81 H. sapiens mRNA for phosphorylase-kinase, beta subunit ATGGCCTCCT 1360 19  5-76 3.84 Human syntaxin mRNA, complete cds AACTGTCCTT 1361 34   5-138 3.84 H. sapiens mRNA for major astrocytic phosphoprotein PEA-15 AAGGAATCGG 1362 34   5-138 3.85 PROTEASOME BETA CHAIN PRECURSOR TCTGTTTATC 1363 29   8-119 3.86 Signal recognition particle 14 kD protein ACTTTTTCAA 1364 704   20-2741 3.87 Tag matches mitochondrial sequence TCTGTAATCC 1365 46   8-185 3.87 Tag matches mitochondrial sequence TCTGTAATCC 1366 46   8-185 3.87 Human aryl sulfotransferase mRNA, complete cds GTGAAAACCC 1367 27   5-110 3.90 No match GGCAGGCACA 1368 24  5-97 3.91 H. sapiens mRNA for phenylalkylamine binding protein GGGGCAGGGC 1369 281   33-1138 3.93 ESTs, Weakly similar to EPIDERMAL GROWTH FACTOR PRECURSOR KIDNEY GGGGCAGGGC 1370 281   33-1138 3.93 Eukaryotic translation Initiation factor 5A GTGAAACTCT 1371 32   8-134 3.94 No match TGGACCAGGC 1372 28   7-118 3.95 Weakly similar to No definition line found [C. elegans] CCTATAATCC 1373 109  16-452 4.01 Retinoblastoma-like 1 (p107) CCTATAATCC 1374 109  16-452 4.01 Cyclic nucleotide gated channel (photoreceptor), cGMP gated 2 (beta) CCTATAATCC 1375 109  16-452 4.01 Homo sapiens mRNA for KIAA0694 protein, complete cds AACTGCTTCA 1376 77  12-323 4.05 Homo sapiens Arp2/3 protein complex subunit p41-Arc (ARC41) mRNA, complete cds GGATTGTCTG 1377 55  11-233 4.07 Small nuclear ribonucleoprotein polypeptides B and B1 CCTGTAATTC 1378 48   8-201 4.07 Homo sapiens mRNA for KIAA0591 protein, partial cds CTGGGCCTGG 1379 84   7-351 4.07 Human HU-K4 mRNA, complete cds ACCCTTGGCC 1380 551   83-2334 4.08 Tag matches mitochondrial sequence ATGGCGATCT 1381 27   7-117 4.09 Ribosomal protein S24 TTGTCTGCCT 1382 39   8-166 4.10 ESTs TGAATCTGGG 1383 35   6-150 4.11 SET translocation (myelold leukemia-associated) AGCCTTTGTT 1384 57   6-240 4.13 Human mRNA for collagen binding protein 2, complete cds CTTTTCAGGA 1385 29   9-129 4.17 Human 14-3-3 epsilon RNA, complete cds CCTGGAGTGG 1386 28   5-123 4.17 ESTs CGGAGACCCT 1387 87  14-380 4.20 Homo sapiens dbpB-Iike protein mRNA, complete cds CCCTGGGTTC 1388 1027   93-4414 4.21 Ferritin, light polypeptide ATTTGAGAAG 1389 643   93-2814 4.23 Tag matches mitochondrial sequence ACAACTCAAT 1390 61   6-265 4.24 ESTs, Highly similar to BRAIN PROTEIN 13 [Mus musculus] CTTGATTCCC 1391 45   8-202 4.30 Homo sapiens quiescin (Q6) mRNA, complete cds GGCTGGTCTC 1392 48   9-216 4.32 ESTs AGGTGGCAAG 1393 194  45-891 4.36 Tag matches mitochondrial sequence CTAGCTTTTA 1394 46  10-210 4.36 Tag matches mitochondrial sequence TCACCGGTCA 1395 143  23-648 4.38 GELSOLIN PRECURSOR, PLASMA GGCCGCGTTC 1396 110   5-487 4.38 Ribosomal protein S17 GAGAGCTCCC 1397 64   6-290 4.41 Tag matches mitochondrial sequence GAGAGCTCCC 1398 64   6-290 4.41 EST GAGAGCTCCC 1399 64   6-290 4.41 ESTs GAGAGCTCCC 1400 64   6-290 4.41 Homo sapiens clone 24751 unknown mRNA CCCCGTACAT 1401 122   7-549 4.43 No match TGGCGTACGG 1402 67  11-314 4.50 Tag matches ribosomal RNA sequence TCCCCGACAT 1403 97   5-444 4.53 No match CCTGGCTAAT 1404 32  11-155 4.53 No match TCACAGCTGT 1405 50  10-238 4.61 B-cell translocation gene 1, anti-proliferative TCCCATTAAG 1406 119  12-560 4.61 No match GTGCACTGAG 1407 259   21-1228 4.65 Major histocompatibility complex, class I, C GTGCACTGAG 1408 259   21-1228 4.65 MHC class I protein HLA-A (HLA-A28,-B40,-Cw3) GCTTACCTTT 1409 35   6-170 4.68 Homo sapiens calumein (Calu) mRNA, complete cds CTGGCCCGGA 1410 54   7-264 4.71 Vasodilator-stimulated phosphoprotein CTGGCCCGGA 1411 54   7-264 4.71 Homo sapiens Sox-like transcriptional factor mRNA, complete cds GGGCCTGTGC 1412 133  11-647 4.79 Homo sapiens monocarboxylate transporter (MCT3) mRNA, complete cds GGGCCTGTGC 1413 133  11-647 4.79 ESTs GCCCCTCCGG 1414 121  18-598 4.79 ESTs, Weakly similar to TRANS-ACTING TRANSCRIPTIONAL PROTEIN ICP0 TTGTGATGTA 1415 21   5-109 4.87 Neurotrophic tyrosine kinase, receptor, type 1 TTGTGATGTA 1416 21   5-109 4.87 Fibroblast growth factor receptor 4 CATCTTCACC 1417 62   5-311 4.97 Ribosomal protein S25 TTGGCCAGGA 1418 100  35-539 5.06 No match AGAATCACTT 1419 37   5-194 5.09 No match TTAGCCAGGA 1420 23   8-129 5.22 Human LLGL mRNA, complete cds GTTGTGGTTA 1421 496   43-2646 5.25 BETA-2-MICROGLOBULIN PRECURSOR CAAGCATCCC 1422 547   36-2910 5.26 Tag matches mitochondrial sequence GACATATGTA 1423 39   8-217 5.29 Cytochrome c oxidase subunit VIIb AGTATCTGGG 1424 63   6-337 5.29 Homo sapiens Arp2/3 protein complex subunit p41-Arc (ARC41 ) mRNA, complete cds ACCGCCTGTG 1425 120  19-659 5.35 Human transcriptional activator mRNA, complete cds CTCTTCGAGA 1426 177  15-963 5.35 Glutathione peroxidase 1 ATGAGCTGAC 1427 104  11-571 5.42 CYSTATIN B GCCTCTGTCT 1428 36   5-202 5.43 Ribosomal protein, large, P1 AAGGAAGATC 1429 38   6-214 5.43 Human glutathione-S-transferase homolog mRNA, complete cds AAAACATTCT 1430 306   30-1698 5.45 Tag matches mitochondrial sequence CTCAGACAGT 1431 64   5-385 5.95 ESTs, Highly similar to 40S RIBOSOMAL PROTEIN S27 [Rattus norvegicus] CCCAAGCTAG 1432 435   54-2698 6.08 Heat shock 27 kD protein 1 CCCAAGCTAG 1433 435   54-2698 6.08 Tag matches ribosomal RNA sequence TCAATCAAGA 1434 34   8-236 6.67 Tyrosine 3-monooxygenase/tryptophan 5-monooxygenase activation protein, eta polypeptide TGCAGCGCCT 1435 111   9-762 6.80 H. sapiens mRNA for uridine phosphorylase TTCACTGTGA 1436 223    7-1557 6.94 Lectin, galactoside-binding, soluble, 3 (galectln 3) (NOTE: redefinition of symbol) CTGACCTGTG 1437 226   16-1663 7.38 HLA CLASS I HISTOCOMPATIBILITY ANTIGEN, B-27 ALPHA CHAIN PRECURSOR GGGGTCAGGG 1438 118   9-882 7.43 Glycogen phospholase B (brain form) GGCTTTAGGG 1439 125   10-1019 8.05 Tag matches mitochondrial sequence TGGGTGAGCC 1440 304   45-2536 8.21 Cathepsin B AGGGTGTTTT 1441 78   8-668 8.43 Dual specificity tyrosine-(Y)-phosphorylation regulated kinase AGGGTGTTTT 1442 78   8-668 8.43 Tag matches mitochondrial sequence TGGTGTATGC 1443 93   6-810 8.62 Tag matches mitochondrial sequence GAGTAGAGAA 1444 50   8-465 9.15 SET translocatlon (myeloid leukemia-associated) TGCAGGCCTG 1445 115   11-1165 10.02 TRYPTOPHANY L-TRNA SYNTHETASE GCGAAACCCT 1446 210   34-2242 10.51 V-erb-b2 avian erythroblastic leukemia viral oncogene homolog 3 (alternative products) GTGACCACGG 1447 4374    29-47260 10.80 Human N-methyl-D-aspartate receptor 2C subunit precursor (NMDAR2C) mRNA, complete cds GTGACCACGG 1448 4374    29-47260 10.80 Tag matches ribosomal RNA sequence

[0237] TABLE 5 Transcripts uniformly elevated in cancer tissues phl,90 Cancer tissues Normal Tissues Avg Tag Sequence SEQ ID NO: CC BC BrC LC M NC NB NBr NL NM T/N UniGene Description ATGTGTAACG 226 93 72 13 5 48 0 0 3 0 0 30 S100 calcium-binding protein A4 (calcium protein, calvasculin, metastasin) CCCTGCCTTG 227 53 66 120 56 20 21 27 0 8 0 21 Midklne (neurite growth-promoting factor 2) GTGCGCTGAG 228 85 103 380 23 58 0 30 56 0 8 18 Major histocompatibility complex, class I, C CTGGCCGCTC 229 26 19 53 16 25 3 1 0 0 5 14 Apoptosis inhibitor 4 (survivin) GCCCCCCCGT 230 38 40 54 31 29 9 7 3 3 0 12 ESTs TGGCCCCAGG 231 13 201 8 24 336 0 30 3 3 19 9 Apollpoprotein CI CCCTGGTGGG 232 16 14 17 16 6 0 0 0 0 3 9 ESTs AGTGACCGAA 233 5 8 37 8 7 0 1 0 3 0 8 ESTs CTGCACTTAC 234 52 34 81 64 78 3 12 22 5 30 8 DNA REPLICATION LICENSING FACTOR CDC47 HOMOLOG CTGGCGAGCG 235 168 137 290 73 178 9 21 64 13 60 8 Human ubiquitin carrier protein (E2-EPF) mRNA, complete cds TTGCCGCTGC 236 4 10 12 19 7 0 1 0 0 0 7 ESTs TGCGCTGGCC 237 22 63 74 28 14 6 18 6 8 0 7 No match CTCCTGGAAC 238 20 10 26 18 18 3 4 0 8 5 6 ESTs, Highly similar to MYO-INOSITOL-1-PHOSPHATE SYNTHASE (Arabidopsis thalianal CGCCCGTCGT 239 4 151 30 9 30 0 13 6 0 5 6 No match TTGCCCCCGT 240 10 61 15 19 23 0 22 6 5 0 6 AXL receptor tyrosine kinase TTGCTAAAGG 241 8 8 16 16 22 3 0 3 8 0 6 ESTs, Weakly similar to KIAA0005 [H.sapiens] AGCCACGTTG 242 13 8 11 11 6 0 0 0 0 3 6 Acid phosphalase 1, soluble CCTGGGCACT 243 14 6 23 22 8 3 1 3 3 0 6 ESTs, Highly similar to transcription factor ARF6 chain B [M.musculus] GGGCTCACCT 244 23 13 52 16 17 3 4 6 3 5 6 Homo sapiens clone 24767 mRNA sequence/ESTs, Weakly similar to colt[D.melanogaster] CTTACAGCCA 245 11 6 19 12 6 0 0 3 0 3 6 ESTs AGGGCCCTCA 246 14 6 15 5 4 0 3 0 0 0 6 Homo sapiens mRNA, complete cds GGGTAATGTG 247 7 13 5 11 12 0 1 0 0 5 5 ESTs, Moderately similar to unknown [M.musculus] CTGACAGCCC 248 4 5 17 7 9 0 1 0 0 3 5 Human mRNA for HsMcm6, complete cds TGACCTCCAG 249 7 14 15 12 11 0 6 3 3 0 5 ESTs, Weakly sImilar to No definition line found [C.elegans]/ESTs AAACCTCTTC 250 10 5 12 11 8 0 1 3 0 3 5 ESTs, Highly similar to G2/MITOTIC-SPECIFIC CYCLIN B2 [Mesocricetus auratus] TCATTGCACT 251 7 13 5 4 9 3 1 0 0 0 5 ESTs, Highly similar to HYPOTHETICAL 16.3 KD PROTEIN [Saccharomyces cerevisiae] CCCCCTCCGG 252 31 14 73 38 58 15 3 8 19 11 5 Small nuclear ribonucleoprotein polypeptide N/B and B1 GTAGGGGCCT 253 11 14 11 19 18 3 6 0 3 8 4 ESTs GAACCCAAAG 254 7 8 12 8 10 0 0 3 3 3 4 Plasminogen/PEPTIDYL-PROLYL CIS-TRANS ISOMERASE A TGTGAGCCTC 255 5 11 11 7 7 0 3 0 0 3 4 Cyclin F ATCTCTGGAG 256 7 3 9 8 7 0 0 0 0 3 4 ESTs AAAGTGCATC 257 10 19 11 4 7 0 9 0 0 3 4 No match GCCTTGGGTG 258 7 8 4 9 10 3 3 0 0 0 4 Leukemia inhibitory factor (cholinergic differentiation factor) ACCTCACTCT 259 9 3 12 16 9 0 0 6 3 3 4 ESTs TAAAGACTTG 260 9 13 24 12 38 3 1 11 5 11 4 Adenylate kinase 2 (adk2) TCGGCGCCGG 261 15 16 21 14 6 6 3 8 3 0 4 SET translocation (myeloid leukemia-associated) AACCTCGAGT 262 6 10 7 8 11 0 4 0 3 3 4 ESTs, Moderately similar to putative [M.musculus] GTTTACCCGC 263 6 3 4 7 4 0 0 0 0 0 3 No match GCCTCTGCCT 264 4 5 5 5 6 0 0 0 0 3 3 ESTs CCTGGGTCCT 265 4 10 8 5 7 0 4 3 0 3 3 ESTs

[0238] TABLE 6 Transcripts expressed in Colon Cancer Cells (>500 copies per cell) Tag SEQ ID NO: Copies/cell Unigene Description CCCATCGTCC 1449 2672 Tag matches mitochondrial sequence TGTGTTGAGA 1450 1672 Translation elongation factor 1-alpha-1 GGATTTGGCC 1451 1663 Ribosomal protein. large P2/Ribosomal protein S26/Human mRNA for PG-B, complete cds CCCGTCCGGA 1452 1559 60S RIBOSOMAL PROTEIN L13 ATGGCTGGTA 1453 1555 40S RIBOSOMAL PROTEIN S2 GTGAAACCCC 1454 1482 Multiple matches CCTCCAGCTA 1455 1468 Keratin 8 TTGGTCCTCT 1456 1453 60S RIBOSOMAL PROTEIN L41 TGATTTCACT 1457 1434 EST/Tag matches mitochondrial sequence CCTGTAATCC 1458 1372 Multiple matches ACTTTTTCAA 1459 1367 Tag matches mitochondrial sequence AAAAAAAAAA 1460 1357 Multiple matches GAGGGAGTTT 1461 1290 Ribosomal protein L27a GCCGAGGAAG 1462 1141 Human mRNA for ribosomal protein S12 CACCTAATTG 1463 1137 Tag matches mitochondrial sequence CGCCGCCGGC 1464 1098 Human ribosomal protein L35 mRNA, complete cds GGGGAAATCG 1465 1092 THYMOSIN BETA-10 GAAAAATGGT 1466 1056 Laminin receptor (2H5 epitope) GGGCTGGGGT 1467 1028 H.sapiens mRNA for ribosomal protein L29/Homo sapiens sperm acrosomal protein mRNA GCCGGGTGGG 1468 986 Basigin AGCCCTACAA 1469 945 Tag matches mitochondrial sequence CTGGGTTAAT 1470 943 40S RIBOSOMAL PROTEIN S19 CAAACCATCC 1471 927 Keratin 18 TGCACGTTTT 1472 916 Human mRNA for antileukoprotease (ALP) from cervix uterus AGGCTACGGA 1473 905 60S RIBOSOMAL PROTEIN L13A GCAGCCATCC 1474 861 Ribosomal protein L28 TTCAATAAAA 1475 851 Ribosomal protein, large, P1/TRANSCOBALAMIN/PRECURSOR CTAAGACTTC 1476 833 Tag matches mitochondrial sequence TGGTGTTGAG 1477 830 Human DNA sequence from clone 1033B10 on chromosome 6p21.2-21.31 TACCATCAAT 1478 828 Glyceraldehyde-3-phosphate dehydrogenase TTCATACACC 1479 814 Tag matches mitochondrial sequence CCACTGCACT 1480 800 Multiple matches ACTAACACCC 1481 795 Tag matches mitochondrial sequence AAGGTGGAGG 1482 794 60S RIBOSOMAL PROTEIN L18A AGCACCTCCA 1483 787 Eukaryolic translation elongation factor 2 CACAAACGGT 1484 761 40S RIBOSOMAL PROTEIN S27 AGGAAAGCTG 1485 732 ESTs, Highly similar to 60S RIBOSOMAL PROTEIN L36 [Rattus norvegicus] GTGAAACCCT 1486 729 Multiple matches AATCCTGTGG 1487 711 Ribosomal protein L8 TTGGGGTTTC 1488 698 Fernitin heavy chain AAGACAGTGG 1489 696 Ribosomal protein L37a ATTTGAGAAG 1490 680 Tag matches mitochondrial sequence GCCGTGTCCG 1491 679 Human ribosomal protein S6 mRNA, complete cds CGCCGGAACA 1492 678 Ribosomal protein L4 TCTCCATACC 1493 661 Tag matches mitochondrial sequence ACATCATCGA 1494 661 Ribosomal protein L12 AACGCGGCCA 1495 644 Macro migration inhibitory factor AGGGCTTCCA 1496 643 UBIQUINOL-CYTOCHROME C REDUCTASE COMPLEX SUBUNIT VI REQUIRING PROTEIN CCGTCCAAGG 1497 631 Ribosomal protein S16 CGCTGGTTCC 1498 626 Homo sapiens ribosomal protein L11 mRNA, complete cds CTCAACATCT 1499 615 Ribosomal protein, large, P0 ACTCCAAAAA 1500 608 H.sapiens mRNA for transmembrane protein mp24/Human insulinoma rig-analog mRNA encoding DNA-binding protein CCTAGCTGGA 1501 606 PEPTIDYL-PROLYL CIS-TRANS ISOMERASE A GTGAAGGCAG 1502 596 Ribosomal protein S3A AGCTCTCCCT 1503 551 60S RIBOSOMAL PROTEIN L23 TAGGTTGTCT 1504 537 TRANSLATIONALLY CONTROLLED TUMOR PROTEIN GGACCACTGA 1505 522 Ribosomal protein L3 AAGGAGATGG 1506 521 Ribosomal protein L31 AACTAAAAAA 1507 510 Ubiquitin A-52 residue ribosomal protein fusion product 1 GGCTGGGGGC 1508 507 Human profillin mRNA, complete cds CCAGAACAGA 1509 503 Deoxythymidylate kinase/60S RIBOSOMAL PROTEIN L30

[0239] TABLE 7 Expressed transcripts (>500 copies per cell) Tag Sequence SEQ ID NO: Copies/Cell Description CCCATCGTCC 1508 3022 Tag matches mitochondrial sequence GTGACCACGG 1509 2435 Tag matches ribosomal RNA sequence/Human N-methyl-D-aspartate receptor 2C subunit precursor (NMDAR2C) mRNA TGTGTTGAGA 1510 1557 Translation elongation factor 1-alpha-1 GTGAAACCCC 1511 1466 Multiple matches CCTGTAATCC 1512 1403 Multiple matches CTAAGACTTC 1513 1349 Tag matches mitochondrial sequence CACCTAATTG 1514 1333 Tag matches mitochondrial sequence CCCGTCCGGA 1515 1282 60S RIBOSOMAL PROTEIN L13 TTGGTCCTCT 1516 1238 60S RIBOSOMAL PROTEIN L41 ATGGCTGGTA 1517 1126 40S RIBOSOMAL PROTEIN S2 TTGGGGTTTC 1518 1099 Ferritin heavy chain CCACTGCACT 1519 964 Multiple matches TGATTTCACT 1520 942 Tag matches mitochondrial sequence/EST ACTTTTTCAA 1521 899 Tag matches mitochondrial sequence GCAGCCATCC 1522 866 Ribosomal protein L28 TACCATCAAT 1523 874 Glyceraldehyde-3-phosphate dehydrogenase GGATTTGGCC 1524 854 Ribosomal protein, large P2/Ribosomal protein S26/Human mRNA for PIG-B CCCTGGGTTC 1525 844 Ferritin, light polypeptide GCCGAGGAAG 1526 836 Human mRNA for ribosomal protein S12 AGGCTACGGA 1527 820 60S RIBOSOMAL PROTEIN L13A CGCCGCCGGC 1528 805 Human ribosomal protein L35 mRNA, complete cds TTCATACACC 1529 804 Tag matches mitochondrial sequence AGCCCTACAA 1530 801 Tag matches mitochondrial sequence CACAAACGGT 1531 799 40S RIBOSOMAL PROTEIN S27 AAGGTGGAGG 1532 786 60S RIBOSOMAL PROTEIN L18A CTTCCTTGCC 1533 777 Keratin 17 TGGTGTTGAG 1534 770 Human DNA sequence from clone 1033810 on chromosome 6p21.2-21.31 GTGAAACCCT 1535 728 Multiple matches GGGGAAATCG 1536 724 THYMOSIN BETA-10 AGCACCTCCA 1537 718 Eukaryotic translation elongation factor 2 CCTCCAGCTA 1538 711 Keratin 8 AAGACAGTGG 1539 699 Ribosomal protein L37a CTGGGTTAAT 1540 699 40S RIBOSOMAL PROTEIN S19 ATTTGAGAAG 1541 689 Tag matches mitochondrial sequence GCCGGGTGGG 1542 687 Basigin GGGCTGGGGT 1543 683 H.sapiens mRNA for ribosomal protein L29/Homo sapiens sperm acrosomal protein mRNA AGGGCTTCCA 1544 663 UBIQUINOL-CYTOCHROME C REDUCTASE COMPLEX SUBUNIT VI REQUIRING PROTEIN AAAAAAAAAA 1545 650 Multiple matches GAGGGAGTTT 1546 648 Ribosomal protein L27a GCGACCGTCA 1547 637 Aldolase A ACTAACACCC 1548 631 Tag matches mitochondrial sequence CGCCGGAACA 1549 616 Ribosomal protein L4 TGGGCAAAGC 1550 592 Translation elongation factor 1 gamma TGCACGTTTT 1551 586 Human mRNA for antileukoprotease (ALP) from cervix uterus AATCCTGTGG 1552 569 Ribosomal protein L8 CAAGCATCCC 1553 565 Tag matches mitochondrial sequence CCGTCCAAGG 1554 559 Ribosomal protein S16 TAGGTTGTCT 1555 551 TRANSLATIONALLY CONTROLLED TUMOR PROTEIN GCCGTGTCCG 1556 540 Human ribosomal protein S6 mRNA, complete cds GCTTTATTTG 1557 540 Human mRNA fragment encoding cytoplasmic actin CTAGCCTCAC 1556 539 Actin, gamma 1 CCTAGCTGGA 1559 537 PEPTIDYL-PROLYL CIS-TRANS ISOMERASE A GCCCCTGCTG 1560 534 Keratin 5 (epidermolysis bullosa simplex, Dowling-Meara/Kobner/Weber-Cockayne types) ACCCTTGGCC 1561 526 Tag matches mitochondrial sequence AGGAAAGCTG 1562 513 ESTs, Highly similar to 60S RIBOSOMAL PROTEIN L36 [Rattus norvegicus]

[0240]

1 1564 1 10 DNA Homo sapiens 1 atactccact 10 2 10 DNA Homo sapiens 2 tcagctgcaa 10 3 10 DNA Homo sapiens 3 gtcatcacca 10 4 10 DNA Homo sapiens 4 ccttcaaatc 10 5 10 DNA Homo sapiens 5 acacccatca 10 6 10 DNA Homo sapiens 6 ccaacaccag 10 7 10 DNA Homo sapiens 7 aatagtttcc 10 8 10 DNA Homo sapiens 8 ccaggcgtca 10 9 10 DNA Homo sapiens 9 gaacagctca 10 10 10 DNA Homo sapiens 10 tactcggcca 10 11 10 DNA Homo sapiens 11 gggggagaag 10 12 10 DNA Homo sapiens 12 agtgggctca 10 13 10 DNA Homo sapiens 13 gagcaccgtg 10 14 10 DNA Homo sapiens 14 gatctatcca 10 15 10 DNA Homo sapiens 15 gaacgccaga 10 16 10 DNA Homo sapiens 16 gccctcggag 10 17 10 DNA Homo sapiens 17 acaagcctag 10 18 10 DNA Homo sapiens 18 gtcacaggaa 10 19 10 DNA Homo sapiens 19 gccctcggag 10 20 10 DNA Homo sapiens 20 ctaggatgat 10 21 10 DNA Homo sapiens 21 ccaactatcg 10 22 10 DNA Homo sapiens 22 ctgacgggga 10 23 10 DNA Homo sapiens 23 gagggtttta 10 24 10 DNA Homo sapiens 24 ggggtcccat 10 25 10 DNA Homo sapiens 25 gccaggtcac 10 26 10 DNA Homo sapiens 26 agaacaccaa 10 27 10 DNA Homo sapiens 27 aatcccgccc 10 28 10 DNA Homo sapiens 28 acactgcctc 10 29 10 DNA Homo sapiens 29 agagtccagg 10 30 10 DNA Homo sapiens 30 ccagacgtag 10 31 10 DNA Homo sapiens 31 gaggcccccg 10 32 10 DNA Homo sapiens 32 ctgtgtgccc 10 33 10 DNA Homo sapiens 33 gagaggatgg 10 34 10 DNA Homo sapiens 34 ggctgaacca 10 35 10 DNA Homo sapiens 35 ccaaatcatt 10 36 10 DNA Homo sapiens 36 acggctgggc 10 37 10 DNA Homo sapiens 37 accttcatct 10 38 10 DNA Homo sapiens 38 agggcttgag 10 39 10 DNA Homo sapiens 39 accttcatct 10 40 10 DNA Homo sapiens 40 tcaggccaga 10 41 10 DNA Homo sapiens 41 ctgtgtgccc 10 42 10 DNA Homo sapiens 42 ggatgtcaac 10 43 10 DNA Homo sapiens 43 atctggagca 10 44 10 DNA Homo sapiens 44 gagaggatgg 10 45 10 DNA Homo sapiens 45 atctggagca 10 46 10 DNA Homo sapiens 46 ggatgtcaac 10 47 10 DNA Homo sapiens 47 cacagacaca 10 48 10 DNA Homo sapiens 48 tgctcctaac 10 49 10 DNA Homo sapiens 49 tatacccgga 10 50 10 DNA Homo sapiens 50 tatcctgatg 10 51 10 DNA Homo sapiens 51 ggccctcccg 10 52 10 DNA Homo sapiens 52 gtagcgatgg 10 53 10 DNA Homo sapiens 53 gcaggttgtg 10 54 10 DNA Homo sapiens 54 tgggaaccgg 10 55 10 DNA Homo sapiens 55 acacctctct 10 56 10 DNA Homo sapiens 56 ggaaaacagg 10 57 10 DNA Homo sapiens 57 caggcggcac 10 58 10 DNA Homo sapiens 58 caggttggtc 10 59 10 DNA Homo sapiens 59 gggatataaa 10 60 10 DNA Homo sapiens 60 gtggaaaatc 10 61 10 DNA Homo sapiens 61 gtgtgtgaat 10 62 10 DNA Homo sapiens 62 atgtgacact 10 63 10 DNA Homo sapiens 63 atggtgtaat 10 64 10 DNA Homo sapiens 64 tcacattgat 10 65 10 DNA Homo sapiens 65 taactaaaca 10 66 10 DNA Homo sapiens 66 tgcccgggtc 10 67 10 DNA Homo sapiens 67 tagtcggaaa 10 68 10 DNA Homo sapiens 68 gctatacggg 10 69 10 DNA Homo sapiens 69 tcacacccca 10 70 10 DNA Homo sapiens 70 ctgcccgaac 10 71 10 DNA Homo sapiens 71 agtcacctct 10 72 10 DNA Homo sapiens 72 tcattggttt 10 73 10 DNA Homo sapiens 73 tcctctcctc 10 74 10 DNA Homo sapiens 74 cctctcggcc 10 75 10 DNA Homo sapiens 75 ccactgaagt 10 76 10 DNA Homo sapiens 76 ctggcttgct 10 77 10 DNA Homo sapiens 77 gaaaacagaa 10 78 10 DNA Homo sapiens 78 aaagcacgtc 10 79 10 DNA Homo sapiens 79 gaaaacagaa 10 80 10 DNA Homo sapiens 80 ttgattccat 10 81 10 DNA Homo sapiens 81 aaacaggcac 10 82 10 DNA Homo sapiens 82 cttacagtcc 10 83 10 DNA Homo sapiens 83 gaatggactc 10 84 10 DNA Homo sapiens 84 gaacccaaac 10 85 10 DNA Homo sapiens 85 gaaaacagaa 10 86 10 DNA Homo sapiens 86 actttgtccc 10 87 10 DNA Homo sapiens 87 gtgcgaatcc 10 88 10 DNA Homo sapiens 88 caaaaagtta 10 89 10 DNA Homo sapiens 89 ttaactttat 10 90 10 DNA Homo sapiens 90 cagccaaatg 10 91 10 DNA Homo sapiens 91 gcctgtggtg 10 92 10 DNA Homo sapiens 92 cttagggaca 10 93 10 DNA Homo sapiens 93 ttggaggtga 10 94 10 DNA Homo sapiens 94 attccatttc 10 95 10 DNA Homo sapiens 95 attccatttc 10 96 10 DNA Homo sapiens 96 agagagcgga 10 97 10 DNA Homo sapiens 97 ttctcaatac 10 98 10 DNA Homo sapiens 98 catcctccca 10 99 10 DNA Homo sapiens 99 gtatcgattt 10 100 10 DNA Homo sapiens 100 ttgtaaacag 10 101 10 DNA Homo sapiens 101 gccctgtatt 10 102 10 DNA Homo sapiens 102 ccacattgcc 10 103 10 DNA Homo sapiens 103 cagggcaacg 10 104 10 DNA Homo sapiens 104 aaaagcaaat 10 105 10 DNA Homo sapiens 105 accaatccta 10 106 10 DNA Homo sapiens 106 ctgtgtgtcc 10 107 10 DNA Homo sapiens 107 tcagacaata 10 108 10 DNA Homo sapiens 108 tggtgagatg 10 109 10 DNA Homo sapiens 109 attttttgtt 10 110 10 DNA Homo sapiens 110 acattgagtc 10 111 10 DNA Homo sapiens 111 gtcagtctac 10 112 10 DNA Homo sapiens 112 gtcccacttc 10 113 10 DNA Homo sapiens 113 ggggcccgaa 10 114 10 DNA Homo sapiens 114 tgactcaccc 10 115 10 DNA Homo sapiens 115 gacagcgaca 10 116 10 DNA Homo sapiens 116 ggtgtacata 10 117 10 DNA Homo sapiens 117 tagctataaa 10 118 10 DNA Homo sapiens 118 ggtgtacata 10 119 10 DNA Homo sapiens 119 gtttcatttt 10 120 10 DNA Homo sapiens 120 aataaattgc 10 121 10 DNA Homo sapiens 121 gtttcatttt 10 122 10 DNA Homo sapiens 122 acacattgta 10 123 10 DNA Homo sapiens 123 tacctattgt 10 124 10 DNA Homo sapiens 124 tttagcagaa 10 125 10 DNA Homo sapiens 125 tttagcagaa 10 126 10 DNA Homo sapiens 126 caatttatga 10 127 10 DNA Homo sapiens 127 gtgaaggttt 10 128 10 DNA Homo sapiens 128 tggactttta 10 129 10 DNA Homo sapiens 129 cgatgccacg 10 130 10 DNA Homo sapiens 130 gtgaaggttt 10 131 10 DNA Homo sapiens 131 tggactttta 10 132 10 DNA Homo sapiens 132 ccttcttgtc 10 133 10 DNA Homo sapiens 133 tccattcaag 10 134 10 DNA Homo sapiens 134 cctatgtatc 10 135 10 DNA Homo sapiens 135 acggaccaat 10 136 10 DNA Homo sapiens 136 tattatcttg 10 137 10 DNA Homo sapiens 137 actttatacg 10 138 10 DNA Homo sapiens 138 actttatacg 10 139 10 DNA Homo sapiens 139 cgcagtcccc 10 140 10 DNA Homo sapiens 140 tgtagtgctc 10 141 10 DNA Homo sapiens 141 ctgcttaagt 10 142 10 DNA Homo sapiens 142 acaagtggaa 10 143 10 DNA Homo sapiens 143 aatcccaatg 10 144 10 DNA Homo sapiens 144 actatgcatc 10 145 10 DNA Homo sapiens 145 acgagtcatt 10 146 10 DNA Homo sapiens 146 ttacattgta 10 147 10 DNA Homo sapiens 147 atgccccctc 10 148 10 DNA Homo sapiens 148 ttttattcat 10 149 10 DNA Homo sapiens 149 acagagcatt 10 150 10 DNA Homo sapiens 150 tgaccaatag 10 151 10 DNA Homo sapiens 151 aatcccaatg 10 152 10 DNA Homo sapiens 152 gcgaactggg 10 153 10 DNA Homo sapiens 153 gcaacactaa 10 154 10 DNA Homo sapiens 154 gtaatggatt 10 155 10 DNA Homo sapiens 155 agcagacgtg 10 156 10 DNA Homo sapiens 156 ggattcggtc 10 157 10 DNA Homo sapiens 157 cggaaggcgg 10 158 10 DNA Homo sapiens 158 tgtaagtacg 10 159 10 DNA Homo sapiens 159 gatcagtcat 10 160 10 DNA Homo sapiens 160 gctcagagtt 10 161 10 DNA Homo sapiens 161 taacctcccc 10 162 10 DNA Homo sapiens 162 aggaacaact 10 163 10 DNA Homo sapiens 163 gggtccgtgg 10 164 10 DNA Homo sapiens 164 tagcaaaata 10 165 10 DNA Homo sapiens 165 gctgtgcaca 10 166 10 DNA Homo sapiens 166 cagaaaatca 10 167 10 DNA Homo sapiens 167 gatttgctgg 10 168 10 DNA Homo sapiens 168 gtgccattct 10 169 10 DNA Homo sapiens 169 gatatttgtc 10 170 10 DNA Homo sapiens 170 tatgatttta 10 171 10 DNA Homo sapiens 171 tcactgcaac 10 172 10 DNA Homo sapiens 172 cccagtcaca 10 173 10 DNA Homo sapiens 173 tatgagaacc 10 174 10 DNA Homo sapiens 174 gagtttagtg 10 175 10 DNA Homo sapiens 175 ctccactctg 10 176 10 DNA Homo sapiens 176 atccagtgac 10 177 10 DNA Homo sapiens 177 tgatcttgag 10 178 10 DNA Homo sapiens 178 aatggctgtt 10 179 10 DNA Homo sapiens 179 atactaaaaa 10 180 10 DNA Homo sapiens 180 atactaaaaa 10 181 10 DNA Homo sapiens 181 gtttattaaa 10 182 10 DNA Homo sapiens 182 agaaatcagt 10 183 10 DNA Homo sapiens 183 ttggatatta 10 184 10 DNA Homo sapiens 184 aattgagtag 10 185 10 DNA Homo sapiens 185 tgagtgctgc 10 186 10 DNA Homo sapiens 186 gcagtacagt 10 187 10 DNA Homo sapiens 187 gaattcagga 10 188 10 DNA Homo sapiens 188 gacttcttta 10 189 10 DNA Homo sapiens 189 gaattcagga 10 190 10 DNA Homo sapiens 190 gtttatactg 10 191 10 DNA Homo sapiens 191 gaattcagga 10 192 10 DNA Homo sapiens 192 gcccgtgtag 10 193 10 DNA Homo sapiens 193 tggggtgtgc 10 194 10 DNA Homo sapiens 194 aatttttatg 10 195 10 DNA Homo sapiens 195 tcagtgtctg 10 196 10 DNA Homo sapiens 196 ggaggtcagc 10 197 10 DNA Homo sapiens 197 ttcttctcaa 10 198 10 DNA Homo sapiens 198 ttcttctcaa 10 199 10 DNA Homo sapiens 199 ggttgtctct 10 200 10 DNA Homo sapiens 200 ctttgtttac 10 201 10 DNA Homo sapiens 201 cactatagaa 10 202 10 DNA Homo sapiens 202 tttggttaca 10 203 10 DNA Homo sapiens 203 tcaaaacaat 10 204 10 DNA Homo sapiens 204 tttggttaca 10 205 10 DNA Homo sapiens 205 tatagagcaa 10 206 10 DNA Homo sapiens 206 taataaccag 10 207 10 DNA Homo sapiens 207 ttctatactg 10 208 10 DNA Homo sapiens 208 ggaatacggc 10 209 10 DNA Homo sapiens 209 tgaactggca 10 210 10 DNA Homo sapiens 210 aatgttgggg 10 211 10 DNA Homo sapiens 211 cgacaaacta 10 212 10 DNA Homo sapiens 212 gtagcacaga 10 213 10 DNA Homo sapiens 213 accgtcaatc 10 214 10 DNA Homo sapiens 214 tggatcagtc 10 215 10 DNA Homo sapiens 215 tggctcggtc 10 216 10 DNA Homo sapiens 216 gcgactgcga 10 217 10 DNA Homo sapiens 217 gcactagctg 10 218 10 DNA Homo sapiens 218 gcggccggtt 10 219 10 DNA Homo sapiens 219 cggcagtccc 10 220 10 DNA Homo sapiens 220 gcccacctgt 10 221 10 DNA Homo sapiens 221 cggcggatgg 10 222 10 DNA Homo sapiens 222 ccccaggccg 10 223 10 DNA Homo sapiens 223 cccattccaa 10 224 10 DNA Homo sapiens 224 tcaagaggtg 10 225 10 DNA Homo sapiens 225 ataactgttg 10 226 10 DNA Homo sapiens 226 atgtgtaacg 10 227 10 DNA Homo sapiens 227 ccctgccttg 10 228 10 DNA Homo sapiens 228 gtgcgctgag 10 229 10 DNA Homo sapiens 229 ctggccgctc 10 230 10 DNA Homo sapiens 230 gcccccccgt 10 231 10 DNA Homo sapiens 231 tggccccagg 10 232 10 DNA Homo sapiens 232 ccctggtggg 10 233 10 DNA Homo sapiens 233 agtgaccgaa 10 234 10 DNA Homo sapiens 234 ctgcacttac 10 235 10 DNA Homo sapiens 235 ctggcgagcg 10 236 10 DNA Homo sapiens 236 ttgccgctgc 10 237 10 DNA Homo sapiens 237 tgcgctggcc 10 238 10 DNA Homo sapiens 238 ctcctggaac 10 239 10 DNA Homo sapiens 239 cgcccgtcgt 10 240 10 DNA Homo sapiens 240 ttgcccccgt 10 241 10 DNA Homo sapiens 241 ttgctaaagg 10 242 10 DNA Homo sapiens 242 agccacgttg 10 243 10 DNA Homo sapiens 243 cctgggcact 10 244 10 DNA Homo sapiens 244 gggctcacct 10 245 10 DNA Homo sapiens 245 cttacagcca 10 246 10 DNA Homo sapiens 246 agggccctca 10 247 10 DNA Homo sapiens 247 gggtaatgtg 10 248 10 DNA Homo sapiens 248 ctgacagccc 10 249 10 DNA Homo sapiens 249 tgacctccag 10 250 10 DNA Homo sapiens 250 aaacctcttc 10 251 10 DNA Homo sapiens 251 tcattgcact 10 252 10 DNA Homo sapiens 252 ccccctccgg 10 253 10 DNA Homo sapiens 253 gtaggggcct 10 254 10 DNA Homo sapiens 254 gaacccaaag 10 255 10 DNA Homo sapiens 255 tgtgagcctc 10 256 10 DNA Homo sapiens 256 atctctggag 10 257 10 DNA Homo sapiens 257 aaagtgcatc 10 258 10 DNA Homo sapiens 258 gccttgggtg 10 259 10 DNA Homo sapiens 259 acctcactct 10 260 10 DNA Homo sapiens 260 taaagacttg 10 261 10 DNA Homo sapiens 261 tcggcgccgg 10 262 10 DNA Homo sapiens 262 aacctcgagt 10 263 10 DNA Homo sapiens 263 gtttacccgc 10 264 10 DNA Homo sapiens 264 gcctctgcct 10 265 10 DNA Homo sapiens 265 cctgggtcct 10 266 10 DNA Homo sapiens 266 catctaaact 10 267 10 DNA Homo sapiens 267 gggcaagcca 10 268 10 DNA Homo sapiens 268 attcagcacc 10 269 10 DNA Homo sapiens 269 ttgttattgc 10 270 10 DNA Homo sapiens 270 acagggtgac 10 271 10 DNA Homo sapiens 271 gcttccatct 10 272 10 DNA Homo sapiens 272 gcttccatct 10 273 10 DNA Homo sapiens 273 gagggtggcg 10 274 10 DNA Homo sapiens 274 gcagggtggg 10 275 10 DNA Homo sapiens 275 agccctccct 10 276 10 DNA Homo sapiens 276 atggccatag 10 277 10 DNA Homo sapiens 277 gtgggtgtcc 10 278 10 DNA Homo sapiens 278 tgtagtttga 10 279 10 DNA Homo sapiens 279 ggggctgtgg 10 280 10 DNA Homo sapiens 280 ggggctgtgg 10 281 10 DNA Homo sapiens 281 cacgcaatgc 10 282 10 DNA Homo sapiens 282 ctcacacatt 10 283 10 DNA Homo sapiens 283 caaatgagga 10 284 10 DNA Homo sapiens 284 tgtaagtctg 10 285 10 DNA Homo sapiens 285 accaaggagg 10 286 10 DNA Homo sapiens 286 accaaggagg 10 287 10 DNA Homo sapiens 287 accaaggagg 10 288 10 DNA Homo sapiens 288 tgaggcaggg 10 289 10 DNA Homo sapiens 289 tccacgcacc 10 290 10 DNA Homo sapiens 290 tagggcaatc 10 291 10 DNA Homo sapiens 291 ggtagcctgg 10 292 10 DNA Homo sapiens 292 tcaacagcca 10 293 10 DNA Homo sapiens 293 ctctgtgtgg 10 294 10 DNA Homo sapiens 294 cctatttact 10 295 10 DNA Homo sapiens 295 tgcatctggt 10 296 10 DNA Homo sapiens 296 gctctctatg 10 297 10 DNA Homo sapiens 297 gaaggcatcc 10 298 10 DNA Homo sapiens 298 ccactcctca 10 299 10 DNA Homo sapiens 299 gctgtcatca 10 300 10 DNA Homo sapiens 300 cggctggtga 10 301 10 DNA Homo sapiens 301 aagccaggac 10 302 10 DNA Homo sapiens 302 tgagagggtg 10 303 10 DNA Homo sapiens 303 gcgtgatcct 10 304 10 DNA Homo sapiens 304 ctgccaactt 10 305 10 DNA Homo sapiens 305 ccaaacgtgt 10 306 10 DNA Homo sapiens 306 gcgggagggc 10 307 10 DNA Homo sapiens 307 ggccagccct 10 308 10 DNA Homo sapiens 308 ggccagccct 10 309 10 DNA Homo sapiens 309 tgggcaaagc 10 310 10 DNA Homo sapiens 310 gcaaaaccag 10 311 10 DNA Homo sapiens 311 acttacctgc 10 312 10 DNA Homo sapiens 312 gttggtctgt 10 313 10 DNA Homo sapiens 313 tgctactggt 10 314 10 DNA Homo sapiens 314 gacgacacga 10 315 10 DNA Homo sapiens 315 caagtggcaa 10 316 10 DNA Homo sapiens 316 tactcttggc 10 317 10 DNA Homo sapiens 317 gactgtgcca 10 318 10 DNA Homo sapiens 318 ttgccggtta 10 319 10 DNA Homo sapiens 319 cattgcagga 10 320 10 DNA Homo sapiens 320 caggaacggg 10 321 10 DNA Homo sapiens 321 aataggtcca 10 322 10 DNA Homo sapiens 322 acctcaggaa 10 323 10 DNA Homo sapiens 323 atgactcaag 10 324 10 DNA Homo sapiens 324 atgactcaag 10 325 10 DNA Homo sapiens 325 gcctctgcca 10 326 10 DNA Homo sapiens 326 tgcttgtccc 10 327 10 DNA Homo sapiens 327 ggtggcactc 10 328 10 DNA Homo sapiens 328 gggctggggt 10 329 10 DNA Homo sapiens 329 gggctggggt 10 330 10 DNA Homo sapiens 330 cacaaacggt 10 331 10 DNA Homo sapiens 331 cattgaaggg 10 332 10 DNA Homo sapiens 332 gtgactgcca 10 333 10 DNA Homo sapiens 333 gtgactgcca 10 334 10 DNA Homo sapiens 334 aagacagtgg 10 335 10 DNA Homo sapiens 335 ctggctgcaa 10 336 10 DNA Homo sapiens 336 accgggaggt 10 337 10 DNA Homo sapiens 337 atggagactt 10 338 10 DNA Homo sapiens 338 cagctcatct 10 339 10 DNA Homo sapiens 339 acgtggtgat 10 340 10 DNA Homo sapiens 340 gcggtgaggt 10 341 10 DNA Homo sapiens 341 gtggcacacg 10 342 10 DNA Homo sapiens 342 gtgacaacac 10 343 10 DNA Homo sapiens 343 ctgctatacg 10 344 10 DNA Homo sapiens 344 actggctgct 10 345 10 DNA Homo sapiens 345 ggaagcacgg 10 346 10 DNA Homo sapiens 346 ggaagcacgg 10 347 10 DNA Homo sapiens 347 ctgttggtga 10 348 10 DNA Homo sapiens 348 tcagatcttt 10 349 10 DNA Homo sapiens 349 tggaatgctg 10 350 10 DNA Homo sapiens 350 taaggagctg 10 351 10 DNA Homo sapiens 351 ggctttggag 10 352 10 DNA Homo sapiens 352 cgcaccattg 10 353 10 DNA Homo sapiens 353 cgctggttcc 10 354 10 DNA Homo sapiens 354 gggcctgggg 10 355 10 DNA Homo sapiens 355 ctcgaggagg 10 356 10 DNA Homo sapiens 356 ttggtcctct 10 357 10 DNA Homo sapiens 357 tccctggcat 10 358 10 DNA Homo sapiens 358 gggggctgct 10 359 10 DNA Homo sapiens 359 gggggctgct 10 360 10 DNA Homo sapiens 360 ccaccccgaa 10 361 10 DNA Homo sapiens 361 ctgctaggaa 10 362 10 DNA Homo sapiens 362 aactgcggca 10 363 10 DNA Homo sapiens 363 tggagtggag 10 364 10 DNA Homo sapiens 364 tgaaggagcc 10 365 10 DNA Homo sapiens 365 ggggactgaa 10 366 10 DNA Homo sapiens 366 tgcacgtttt 10 367 10 DNA Homo sapiens 367 ctggatgccg 10 368 10 DNA Homo sapiens 368 ccccctcgtg 10 369 10 DNA Homo sapiens 369 atgatgcggt 10 370 10 DNA Homo sapiens 370 attctccagt 10 371 10 DNA Homo sapiens 371 ccccagttgc 10 372 10 DNA Homo sapiens 372 ccaaggattg 10 373 10 DNA Homo sapiens 373 gaccgaggtg 10 374 10 DNA Homo sapiens 374 gactctctca 10 375 10 DNA Homo sapiens 375 gactctggga 10 376 10 DNA Homo sapiens 376 gactctggga 10 377 10 DNA Homo sapiens 377 cgccgcggtg 10 378 10 DNA Homo sapiens 378 ccagaacaga 10 379 10 DNA Homo sapiens 379 ccagaacaga 10 380 10 DNA Homo sapiens 380 tggtttttgg 10 381 10 DNA Homo sapiens 381 tttttgtaca 10 382 10 DNA Homo sapiens 382 gttctcccac 10 383 10 DNA Homo sapiens 383 gaccctgccc 10 384 10 DNA Homo sapiens 384 gcccgccttg 10 385 10 DNA Homo sapiens 385 ggtgctggag 10 386 10 DNA Homo sapiens 386 ttacctcctt 10 387 10 DNA Homo sapiens 387 aaaccagggc 10 388 10 DNA Homo sapiens 388 ttctggctgc 10 389 10 DNA Homo sapiens 389 ttctggctgc 10 390 10 DNA Homo sapiens 390 cttctcaccg 10 391 10 DNA Homo sapiens 391 gagaaccgta 10 392 10 DNA Homo sapiens 392 gcgaccgtca 10 393 10 DNA Homo sapiens 393 gtcaagacca 10 394 10 DNA Homo sapiens 394 ctgggtctcc 10 395 10 DNA Homo sapiens 395 cgattctgga 10 396 10 DNA Homo sapiens 396 caggaggagt 10 397 10 DNA Homo sapiens 397 caaaatcagg 10 398 10 DNA Homo sapiens 398 ctgggttaat 10 399 10 DNA Homo sapiens 399 ttttctgctg 10 400 10 DNA Homo sapiens 400 ccctggcaat 10 401 10 DNA Homo sapiens 401 aggctacgga 10 402 10 DNA Homo sapiens 402 gaggccatcc 10 403 10 DNA Homo sapiens 403 ctttgatgtt 10 404 10 DNA Homo sapiens 404 ttggacctgg 10 405 10 DNA Homo sapiens 405 ttggacctgg 10 406 10 DNA Homo sapiens 406 gttcgtgcca 10 407 10 DNA Homo sapiens 407 gatgctgcca 10 408 10 DNA Homo sapiens 408 acggctccga 10 409 10 DNA Homo sapiens 409 gagtcaggag 10 410 10 DNA Homo sapiens 410 ggaggctgag 10 411 10 DNA Homo sapiens 411 ggaggctgag 10 412 10 DNA Homo sapiens 412 gtgatggtgt 10 413 10 DNA Homo sapiens 413 tcagatggcg 10 414 10 DNA Homo sapiens 414 atgcgaaagg 10 415 10 DNA Homo sapiens 415 tgctgggtgg 10 416 10 DNA Homo sapiens 416 tgctgggtgg 10 417 10 DNA Homo sapiens 417 tcaaatgcat 10 418 10 DNA Homo sapiens 418 tccaaggaag 10 419 10 DNA Homo sapiens 419 cccagggaga 10 420 10 DNA Homo sapiens 420 tggcctgccc 10 421 10 DNA Homo sapiens 421 tggcctgccc 10 422 10 DNA Homo sapiens 422 ggccaaaggc 10 423 10 DNA Homo sapiens 423 ggcctgctgc 10 424 10 DNA Homo sapiens 424 gtgaagctga 10 425 10 DNA Homo sapiens 425 gtgaagctga 10 426 10 DNA Homo sapiens 426 gaaatgtaag 10 427 10 DNA Homo sapiens 427 gaaatgtaag 10 428 10 DNA Homo sapiens 428 cgtgttaatg 10 429 10 DNA Homo sapiens 429 aggggattcc 10 430 10 DNA Homo sapiens 430 cagctcactg 10 431 10 DNA Homo sapiens 431 gtttggcagt 10 432 10 DNA Homo sapiens 432 ggagctctgt 10 433 10 DNA Homo sapiens 433 tggaactgtg 10 434 10 DNA Homo sapiens 434 tctgcttaca 10 435 10 DNA Homo sapiens 435 agggcttcca 10 436 10 DNA Homo sapiens 436 gagcaaacgg 10 437 10 DNA Homo sapiens 437 tgtgatcaga 10 438 10 DNA Homo sapiens 438 acactacggg 10 439 10 DNA Homo sapiens 439 agccaaaaaa 10 440 10 DNA Homo sapiens 440 gcgggtgtgg 10 441 10 DNA Homo sapiens 441 ttgctagagg 10 442 10 DNA Homo sapiens 442 ggggcttctg 10 443 10 DNA Homo sapiens 443 aactcttgaa 10 444 10 DNA Homo sapiens 444 gtctgacccc 10 445 10 DNA Homo sapiens 445 atgtcatcaa 10 446 10 DNA Homo sapiens 446 tctgtcaaga 10 447 10 DNA Homo sapiens 447 gccccagcga 10 448 10 DNA Homo sapiens 448 ggcaagcccc 10 449 10 DNA Homo sapiens 449 ctcatcagct 10 450 10 DNA Homo sapiens 450 ctgttgattg 10 451 10 DNA Homo sapiens 451 gcttttaagg 10 452 10 DNA Homo sapiens 452 gcctgagcct 10 453 10 DNA Homo sapiens 453 gagcgggatg 10 454 10 DNA Homo sapiens 454 ttcacagtgg 10 455 10 DNA Homo sapiens 455 gcccgtgcca 10 456 10 DNA Homo sapiens 456 ccctaggttg 10 457 10 DNA Homo sapiens 457 ccctgatttt 10 458 10 DNA Homo sapiens 458 gtgttaacca 10 459 10 DNA Homo sapiens 459 aggaaagctg 10 460 10 DNA Homo sapiens 460 ttctctctgt 10 461 10 DNA Homo sapiens 461 ttactaaatg 10 462 10 DNA Homo sapiens 462 gggtgtggtg 10 463 10 DNA Homo sapiens 463 ccactgcagt 10 464 10 DNA Homo sapiens 464 agcctggact 10 465 10 DNA Homo sapiens 465 gtggggtgac 10 466 10 DNA Homo sapiens 466 cactacacgg 10 467 10 DNA Homo sapiens 467 ctcatagcag 10 468 10 DNA Homo sapiens 468 ggaatgtacg 10 469 10 DNA Homo sapiens 469 ctgagggtgg 10 470 10 DNA Homo sapiens 470 aaggtcgagc 10 471 10 DNA Homo sapiens 471 gaatcactgc 10 472 10 DNA Homo sapiens 472 acatcatcga 10 473 10 DNA Homo sapiens 473 gaatgaggac 10 474 10 DNA Homo sapiens 474 cctcgctcag 10 475 10 DNA Homo sapiens 475 tcctagcctg 10 476 10 DNA Homo sapiens 476 aggtgcgggg 10 477 10 DNA Homo sapiens 477 ctccaataaa 10 478 10 DNA Homo sapiens 478 gcgctggagt 10 479 10 DNA Homo sapiens 479 aatttgcaac 10 480 10 DNA Homo sapiens 480 aacgcggcca 10 481 10 DNA Homo sapiens 481 ggtgtatatg 10 482 10 DNA Homo sapiens 482 ggcaacaaaa 10 483 10 DNA Homo sapiens 483 ggcaacaaaa 10 484 10 DNA Homo sapiens 484 tttgtgactg 10 485 10 DNA Homo sapiens 485 atgaggccgg 10 486 10 DNA Homo sapiens 486 tcagtttgtc 10 487 10 DNA Homo sapiens 487 ccctattaag 10 488 10 DNA Homo sapiens 488 tttctagttt 10 489 10 DNA Homo sapiens 489 gggcccttcc 10 490 10 DNA Homo sapiens 490 gggcccttcc 10 491 10 DNA Homo sapiens 491 ccttggtttt 10 492 10 DNA Homo sapiens 492 gctaaggaga 10 493 10 DNA Homo sapiens 493 tgaggggtga 10 494 10 DNA Homo sapiens 494 ccagctgcca 10 495 10 DNA Homo sapiens 495 gggctgtttg 10 496 10 DNA Homo sapiens 496 tggacacaag 10 497 10 DNA Homo sapiens 497 tctccaggaa 10 498 10 DNA Homo sapiens 498 tgatgtttga 10 499 10 DNA Homo sapiens 499 gtggtgcacg 10 500 10 DNA Homo sapiens 500 gtctgcacct 10 501 10 DNA Homo sapiens 501 gatgaccccg 10 502 10 DNA Homo sapiens 502 atcaagggtg 10 503 10 DNA Homo sapiens 503 tctggtctgg 10 504 10 DNA Homo sapiens 504 aggatgaccc 10 505 10 DNA Homo sapiens 505 aaagggggca 10 506 10 DNA Homo sapiens 506 ggctttaccc 10 507 10 DNA Homo sapiens 507 gctttttaga 10 508 10 DNA Homo sapiens 508 ctctgctcgg 10 509 10 DNA Homo sapiens 509 gcctgggact 10 510 10 DNA Homo sapiens 510 ggtagcaggg 10 511 10 DNA Homo sapiens 511 gccgatcctc 10 512 10 DNA Homo sapiens 512 gcagctcagg 10 513 10 DNA Homo sapiens 513 cgcagtgtcc 10 514 10 DNA Homo sapiens 514 cccctattaa 10 515 10 DNA Homo sapiens 515 ttgtaaaagg 10 516 10 DNA Homo sapiens 516 ccacaccggt 10 517 10 DNA Homo sapiens 517 cctggaagag 10 518 10 DNA Homo sapiens 518 tagccgctga 10 519 10 DNA Homo sapiens 519 cctaggacct 10 520 10 DNA Homo sapiens 520 gtggaccctg 10 521 10 DNA Homo sapiens 521 gtggaccctg 10 522 10 DNA Homo sapiens 522 ttgggagcag 10 523 10 DNA Homo sapiens 523 gtctcacgtg 10 524 10 DNA Homo sapiens 524 gtactgtggc 10 525 10 DNA Homo sapiens 525 aagataatgc 10 526 10 DNA Homo sapiens 526 aatacctcgt 10 527 10 DNA Homo sapiens 527 accttgtgcc 10 528 10 DNA Homo sapiens 528 accttgtgcc 10 529 10 DNA Homo sapiens 529 ggagggggct 10 530 10 DNA Homo sapiens 530 gcctatggtc 10 531 10 DNA Homo sapiens 531 gtgctgaatg 10 532 10 DNA Homo sapiens 532 tcgtcgcaga 10 533 10 DNA Homo sapiens 533 gtgacagaag 10 534 10 DNA Homo sapiens 534 tcaacggtgt 10 535 10 DNA Homo sapiens 535 gagccttggt 10 536 10 DNA Homo sapiens 536 tacatccgaa 10 537 10 DNA Homo sapiens 537 gtctgtgaga 10 538 10 DNA Homo sapiens 538 gttaacgtcc 10 539 10 DNA Homo sapiens 539 gtgcgctagg 10 540 10 DNA Homo sapiens 540 cggataaggc 10 541 10 DNA Homo sapiens 541 gtctggggct 10 542 10 DNA Homo sapiens 542 catcctgctg 10 543 10 DNA Homo sapiens 543 tcacaagcaa 10 544 10 DNA Homo sapiens 544 ggctgatgtg 10 545 10 DNA Homo sapiens 545 cccgtccgga 10 546 10 DNA Homo sapiens 546 tccgcgagaa 10 547 10 DNA Homo sapiens 547 gtgctggaga 10 548 10 DNA Homo sapiens 548 tcctcaagat 10 549 10 DNA Homo sapiens 549 caacttagtt 10 550 10 DNA Homo sapiens 550 gggcagctgg 10 551 10 DNA Homo sapiens 551 tttcagagag 10 552 10 DNA Homo sapiens 552 tttcagagag 10 553 10 DNA Homo sapiens 553 gacgcagaag 10 554 10 DNA Homo sapiens 554 ggaagtttcg 10 555 10 DNA Homo sapiens 555 gttgctgccc 10 556 10 DNA Homo sapiens 556 gctggggtgg 10 557 10 DNA Homo sapiens 557 ctcaacatct 10 558 10 DNA Homo sapiens 558 caagcaggac 10 559 10 DNA Homo sapiens 559 ttggcttttc 10 560 10 DNA Homo sapiens 560 tggcaacctt 10 561 10 DNA Homo sapiens 561 gcataatagg 10 562 10 DNA Homo sapiens 562 gggggtaact 10 563 10 DNA Homo sapiens 563 ccttcgagat 10 564 10 DNA Homo sapiens 564 cgggccgtgc 10 565 10 DNA Homo sapiens 565 gtgttgcaca 10 566 10 DNA Homo sapiens 566 cctcggaaaa 10 567 10 DNA Homo sapiens 567 aataaaggct 10 568 10 DNA Homo sapiens 568 aataaaggct 10 569 10 DNA Homo sapiens 569 cttctgtgta 10 570 10 DNA Homo sapiens 570 cttctgtgta 10 571 10 DNA Homo sapiens 571 ggtccagtgt 10 572 10 DNA Homo sapiens 572 agcacctcca 10 573 10 DNA Homo sapiens 573 aagctgagtg 10 574 10 DNA Homo sapiens 574 gtttcttccc 10 575 10 DNA Homo sapiens 575 tgagggaata 10 576 10 DNA Homo sapiens 576 agctctccct 10 577 10 DNA Homo sapiens 577 tacgttgcag 10 578 10 DNA Homo sapiens 578 gggtgtgtat 10 579 10 DNA Homo sapiens 579 ggagggatca 10 580 10 DNA Homo sapiens 580 atcagtggct 10 581 10 DNA Homo sapiens 581 ccccctgccc 10 582 10 DNA Homo sapiens 582 ccccctgccc 10 583 10 DNA Homo sapiens 583 caaaaaaaaa 10 584 10 DNA Homo sapiens 584 acctgccgac 10 585 10 DNA Homo sapiens 585 gaccagaaaa 10 586 10 DNA Homo sapiens 586 agccactgcg 10 587 10 DNA Homo sapiens 587 ttgagccagc 10 588 10 DNA Homo sapiens 588 tttcagggga 10 589 10 DNA Homo sapiens 589 tccggccgcg 10 590 10 DNA Homo sapiens 590 gtgatctccg 10 591 10 DNA Homo sapiens 591 ctgctgagtg 10 592 10 DNA Homo sapiens 592 ctgcttaagg 10 593 10 DNA Homo sapiens 593 tgtggcctcc 10 594 10 DNA Homo sapiens 594 cgttttctga 10 595 10 DNA Homo sapiens 595 ggaaaaaaaa 10 596 10 DNA Homo sapiens 596 ggaaaaaaaa 10 597 10 DNA Homo sapiens 597 gagggagttt 10 598 10 DNA Homo sapiens 598 gactcacttt 10 599 10 DNA Homo sapiens 599 gagaacgggg 10 600 10 DNA Homo sapiens 600 tggctagtgt 10 601 10 DNA Homo sapiens 601 ctgtcatttg 10 602 10 DNA Homo sapiens 602 gttccctggc 10 603 10 DNA Homo sapiens 603 gcatttaaat 10 604 10 DNA Homo sapiens 604 atccacatcg 10 605 10 DNA Homo sapiens 605 ctgctgtgat 10 606 10 DNA Homo sapiens 606 gtgacctcct 10 607 10 DNA Homo sapiens 607 gtggacccca 10 608 10 DNA Homo sapiens 608 gactagtgcg 10 609 10 DNA Homo sapiens 609 ttatgggatc 10 610 10 DNA Homo sapiens 610 tttcagattg 10 611 10 DNA Homo sapiens 611 gtctgagctc 10 612 10 DNA Homo sapiens 612 cacacaatgt 10 613 10 DNA Homo sapiens 613 cacacaatgt 10 614 10 DNA Homo sapiens 614 accccaccca 10 615 10 DNA Homo sapiens 615 ggaggcaggt 10 616 10 DNA Homo sapiens 616 tctcaattct 10 617 10 DNA Homo sapiens 617 ctcttcagga 10 618 10 DNA Homo sapiens 618 ctgggactgc 10 619 10 DNA Homo sapiens 619 gcccagcagg 10 620 10 DNA Homo sapiens 620 gcccagcagg 10 621 10 DNA Homo sapiens 621 gggccagggg 10 622 10 DNA Homo sapiens 622 gggggacggc 10 623 10 DNA Homo sapiens 623 actgggtcta 10 624 10 DNA Homo sapiens 624 gccgaggaag 10 625 10 DNA Homo sapiens 625 cagatctttg 10 626 10 DNA Homo sapiens 626 aggtttcctc 10 627 10 DNA Homo sapiens 627 ccgtccaagg 10 628 10 DNA Homo sapiens 628 gtggcgggcg 10 629 10 DNA Homo sapiens 629 gtggcgggcg 10 630 10 DNA Homo sapiens 630 gtggcgggcg 10 631 10 DNA Homo sapiens 631 ggcaagaaga 10 632 10 DNA Homo sapiens 632 tctttacttg 10 633 10 DNA Homo sapiens 633 ctcctcacct 10 634 10 DNA Homo sapiens 634 ctcctcacct 10 635 10 DNA Homo sapiens 635 gcctgtatga 10 636 10 DNA Homo sapiens 636 gctttatttg 10 637 10 DNA Homo sapiens 637 cttaaggatt 10 638 10 DNA Homo sapiens 638 ggatttggcc 10 639 10 DNA Homo sapiens 639 ggatttggcc 10 640 10 DNA Homo sapiens 640 ggatttggcc 10 641 10 DNA Homo sapiens 641 tcctccctcc 10 642 10 DNA Homo sapiens 642 ggccctctga 10 643 10 DNA Homo sapiens 643 tggctgtgtg 10 644 10 DNA Homo sapiens 644 agaccaaagt 10 645 10 DNA Homo sapiens 645 atggccaact 10 646 10 DNA Homo sapiens 646 aggagctgct 10 647 10 DNA Homo sapiens 647 aggagctgct 10 648 10 DNA Homo sapiens 648 tgtacctgta 10 649 10 DNA Homo sapiens 649 gatcccaaca 10 650 10 DNA Homo sapiens 650 ggccatctct 10 651 10 DNA Homo sapiens 651 aggtgcagag 10 652 10 DNA Homo sapiens 652 gtggcatcac 10 653 10 DNA Homo sapiens 653 tgtgttgaga 10 654 10 DNA Homo sapiens 654 ctgagacaaa 10 655 10 DNA Homo sapiens 655 gcaacgggcc 10 656 10 DNA Homo sapiens 656 gctggctggc 10 657 10 DNA Homo sapiens 657 gccaagatgc 10 658 10 DNA Homo sapiens 658 gccaaggggc 10 659 10 DNA Homo sapiens 659 acggtgatgt 10 660 10 DNA Homo sapiens 660 cccatccgaa 10 661 10 DNA Homo sapiens 661 acaaacttag 10 662 10 DNA Homo sapiens 662 gcctcctccc 10 663 10 DNA Homo sapiens 663 gtgcctgaga 10 664 10 DNA Homo sapiens 664 tccaatactg 10 665 10 DNA Homo sapiens 665 gtggtgcgtg 10 666 10 DNA Homo sapiens 666 aagaagcagg 10 667 10 DNA Homo sapiens 667 acttggagcc 10 668 10 DNA Homo sapiens 668 ccgtggtcac 10 669 10 DNA Homo sapiens 669 acagtgggga 10 670 10 DNA Homo sapiens 670 acaaactgtg 10 671 10 DNA Homo sapiens 671 gtcttaactc 10 672 10 DNA Homo sapiens 672 ctgtgctcgg 10 673 10 DNA Homo sapiens 673 gtggcctgca 10 674 10 DNA Homo sapiens 674 tggtacacgt 10 675 10 DNA Homo sapiens 675 gtactgtatg 10 676 10 DNA Homo sapiens 676 gtactgtatg 10 677 10 DNA Homo sapiens 677 ggccaggtgg 10 678 10 DNA Homo sapiens 678 ggccaggtgg 10 679 10 DNA Homo sapiens 679 agggagaggg 10 680 10 DNA Homo sapiens 680 agggagaggg 10 681 10 DNA Homo sapiens 681 agggagaggg 10 682 10 DNA Homo sapiens 682 gtggcaggtg 10 683 10 DNA Homo sapiens 683 tcttgtgcat 10 684 10 DNA Homo sapiens 684 ccacacaccg 10 685 10 DNA Homo sapiens 685 acaaatcctt 10 686 10 DNA Homo sapiens 686 gtgagacccc 10 687 10 DNA Homo sapiens 687 aaagccaaga 10 688 10 DNA Homo sapiens 688 caaggatcta 10 689 10 DNA Homo sapiens 689 tgaggccagg 10 690 10 DNA Homo sapiens 690 ttttgtgtga 10 691 10 DNA Homo sapiens 691 acagtcttgc 10 692 10 DNA Homo sapiens 692 acagtcttgc 10 693 10 DNA Homo sapiens 693 ccaggcacgc 10 694 10 DNA Homo sapiens 694 agtttcccaa 10 695 10 DNA Homo sapiens 695 ccagtggccc 10 696 10 DNA Homo sapiens 696 gccccgccct 10 697 10 DNA Homo sapiens 697 tctctactaa 10 698 10 DNA Homo sapiens 698 cggcttttct 10 699 10 DNA Homo sapiens 699 tggcccccgc 10 700 10 DNA Homo sapiens 700 tggcccccgc 10 701 10 DNA Homo sapiens 701 ctcctggggc 10 702 10 DNA Homo sapiens 702 aaggagctgg 10 703 10 DNA Homo sapiens 703 aaggagctgg 10 704 10 DNA Homo sapiens 704 aaggagctgg 10 705 10 DNA Homo sapiens 705 ggctttgatt 10 706 10 DNA Homo sapiens 706 actaccttca 10 707 10 DNA Homo sapiens 707 ctgtgcattt 10 708 10 DNA Homo sapiens 708 actccaaaaa 10 709 10 DNA Homo sapiens 709 actccaaaaa 10 710 10 DNA Homo sapiens 710 tcctgcccca 10 711 10 DNA Homo sapiens 711 tcctgcccca 10 712 10 DNA Homo sapiens 712 aagctggagg 10 713 10 DNA Homo sapiens 713 gcacaagaag 10 714 10 DNA Homo sapiens 714 gaaaccgagg 10 715 10 DNA Homo sapiens 715 gaaaccgagg 10 716 10 DNA Homo sapiens 716 gcccgcaagc 10 717 10 DNA Homo sapiens 717 ctttcagatg 10 718 10 DNA Homo sapiens 718 gggcgctgtg 10 719 10 DNA Homo sapiens 719 gtattcccct 10 720 10 DNA Homo sapiens 720 gtattcccct 10 721 10 DNA Homo sapiens 721 ctggccatcg 10 722 10 DNA Homo sapiens 722 gtggtggaca 10 723 10 DNA Homo sapiens 723 gtggtggaca 10 724 10 DNA Homo sapiens 724 gtggtggaca 10 725 10 DNA Homo sapiens 725 cacctaattg 10 726 10 DNA Homo sapiens 726 gacccctgtc 10 727 10 DNA Homo sapiens 727 cccttagctt 10 728 10 DNA Homo sapiens 728 cagagacgtg 10 729 10 DNA Homo sapiens 729 atggctggta 10 730 10 DNA Homo sapiens 730 tcagccttct 10 731 10 DNA Homo sapiens 731 tcgtaacgag 10 732 10 DNA Homo sapiens 732 gcgacgaggc 10 733 10 DNA Homo sapiens 733 gcggggtacc 10 734 10 DNA Homo sapiens 734 tccttctcca 10 735 10 DNA Homo sapiens 735 cagtctctca 10 736 10 DNA Homo sapiens 736 acccttccct 10 737 10 DNA Homo sapiens 737 acccttccct 10 738 10 DNA Homo sapiens 738 tgagtggtca 10 739 10 DNA Homo sapiens 739 gacaatgcca 10 740 10 DNA Homo sapiens 740 atctttctgg 10 741 10 DNA Homo sapiens 741 agctgtcccc 10 742 10 DNA Homo sapiens 742 tcttccagga 10 743 10 DNA Homo sapiens 743 gtgcctagga 10 744 10 DNA Homo sapiens 744 tggacccccc 10 745 10 DNA Homo sapiens 745 acctgtatcc 10 746 10 DNA Homo sapiens 746 acctgctggt 10 747 10 DNA Homo sapiens 747 agtctgatgt 10 748 10 DNA Homo sapiens 748 tctctaccca 10 749 10 DNA Homo sapiens 749 tgattaaggt 10 750 10 DNA Homo sapiens 750 cagcagaagc 10 751 10 DNA Homo sapiens 751 tccctattaa 10 752 10 DNA Homo sapiens 752 gtggaggtgc 10 753 10 DNA Homo sapiens 753 aagatccccg 10 754 10 DNA Homo sapiens 754 gagcggcctc 10 755 10 DNA Homo sapiens 755 aactacatag 10 756 10 DNA Homo sapiens 756 gtaagatttg 10 757 10 DNA Homo sapiens 757 agcctgcaga 10 758 10 DNA Homo sapiens 758 ggaccactga 10 759 10 DNA Homo sapiens 759 ttcaataaaa 10 760 10 DNA Homo sapiens 760 ttcaataaaa 10 761 10 DNA Homo sapiens 761 cgatggtccc 10 762 10 DNA Homo sapiens 762 catttgtaat 10 763 10 DNA Homo sapiens 763 cctgagcccg 10 764 10 DNA Homo sapiens 764 tgaggcctct 10 765 10 DNA Homo sapiens 765 aagagttacg 10 766 10 DNA Homo sapiens 766 gaatccaact 10 767 10 DNA Homo sapiens 767 aggggcgcag 10 768 10 DNA Homo sapiens 768 gcttagaagt 10 769 10 DNA Homo sapiens 769 aagtcattca 10 770 10 DNA Homo sapiens 770 aagtcattca 10 771 10 DNA Homo sapiens 771 taccccaccc 10 772 10 DNA Homo sapiens 772 taccccaccc 10 773 10 DNA Homo sapiens 773 cctagctgga 10 774 10 DNA Homo sapiens 774 tcgtctttat 10 775 10 DNA Homo sapiens 775 ggtttggctt 10 776 10 DNA Homo sapiens 776 taggatgggg 10 777 10 DNA Homo sapiens 777 gtgcatcccg 10 778 10 DNA Homo sapiens 778 cagcgctgca 10 779 10 DNA Homo sapiens 779 gggagcccct 10 780 10 DNA Homo sapiens 780 gggagcccct 10 781 10 DNA Homo sapiens 781 gaagatgtgg 10 782 10 DNA Homo sapiens 782 cctaccacag 10 783 10 DNA Homo sapiens 783 tgctaaaaaa 10 784 10 DNA Homo sapiens 784 cacagagtcc 10 785 10 DNA Homo sapiens 785 gggccaataa 10 786 10 DNA Homo sapiens 786 gcctgctggg 10 787 10 DNA Homo sapiens 787 actgcttgcc 10 788 10 DNA Homo sapiens 788 actgcttgcc 10 789 10 DNA Homo sapiens 789 cggttactgt 10 790 10 DNA Homo sapiens 790 aacccgggag 10 791 10 DNA Homo sapiens 791 aacccgggag 10 792 10 DNA Homo sapiens 792 aacccgggag 10 793 10 DNA Homo sapiens 793 attaacaaag 10 794 10 DNA Homo sapiens 794 ttcagtgccc 10 795 10 DNA Homo sapiens 795 ccgtgctcat 10 796 10 DNA Homo sapiens 796 atccctcagt 10 797 10 DNA Homo sapiens 797 taccatcaat 10 798 10 DNA Homo sapiens 798 tgcaccacag 10 799 10 DNA Homo sapiens 799 gaaccctggg 10 800 10 DNA Homo sapiens 800 gccgtgtccg 10 801 10 DNA Homo sapiens 801 atagaggcaa 10 802 10 DNA Homo sapiens 802 attgtttatg 10 803 10 DNA Homo sapiens 803 taataaaggt 10 804 10 DNA Homo sapiens 804 gggatcaagg 10 805 10 DNA Homo sapiens 805 caagggcttg 10 806 10 DNA Homo sapiens 806 tggtgttgag 10 807 10 DNA Homo sapiens 807 gagtgagtga 10 808 10 DNA Homo sapiens 808 gtggcgcaca 10 809 10 DNA Homo sapiens 809 atgatccgga 10 810 10 DNA Homo sapiens 810 aacctgggag 10 811 10 DNA Homo sapiens 811 aacctgggag 10 812 10 DNA Homo sapiens 812 tgcttcatct 10 813 10 DNA Homo sapiens 813 ataattcttt 10 814 10 DNA Homo sapiens 814 gttcagctgt 10 815 10 DNA Homo sapiens 815 gggaagtcac 10 816 10 DNA Homo sapiens 816 gggtgcttgg 10 817 10 DNA Homo sapiens 817 cagttactta 10 818 10 DNA Homo sapiens 818 gcgaaacccc 10 819 10 DNA Homo sapiens 819 gccttccaat 10 820 10 DNA Homo sapiens 820 ccccctggat 10 821 10 DNA Homo sapiens 821 gacctcctgc 10 822 10 DNA Homo sapiens 822 gacctcctgc 10 823 10 DNA Homo sapiens 823 cagcagtagc 10 824 10 DNA Homo sapiens 824 ttcattataa 10 825 10 DNA Homo sapiens 825 cccccaccta 10 826 10 DNA Homo sapiens 826 ggtggatgtg 10 827 10 DNA Homo sapiens 827 tctggtttgt 10 828 10 DNA Homo sapiens 828 tctggtttgt 10 829 10 DNA Homo sapiens 829 cgcctgtaat 10 830 10 DNA Homo sapiens 830 tcctgctgcc 10 831 10 DNA Homo sapiens 831 tcctgctgcc 10 832 10 DNA Homo sapiens 832 gtgtggtggt 10 833 10 DNA Homo sapiens 833 tgatgtccac 10 834 10 DNA Homo sapiens 834 ccaggaggaa 10 835 10 DNA Homo sapiens 835 gtgaagcccc 10 836 10 DNA Homo sapiens 836 gggagcccgg 10 837 10 DNA Homo sapiens 837 gccatcccct 10 838 10 DNA Homo sapiens 838 cagttggttg 10 839 10 DNA Homo sapiens 839 atccatctgt 10 840 10 DNA Homo sapiens 840 gccaggaagc 10 841 10 DNA Homo sapiens 841 tccagcccct 10 842 10 DNA Homo sapiens 842 gccccccact 10 843 10 DNA Homo sapiens 843 tgtctgtggt 10 844 10 DNA Homo sapiens 844 tcccgtacat 10 845 10 DNA Homo sapiens 845 gtggtgggca 10 846 10 DNA Homo sapiens 846 gtggtgggca 10 847 10 DNA Homo sapiens 847 gtggtgggca 10 848 10 DNA Homo sapiens 848 ctgttagtgt 10 849 10 DNA Homo sapiens 849 ctctcaccct 10 850 10 DNA Homo sapiens 850 tgctggtgtg 10 851 10 DNA Homo sapiens 851 ctaagacttc 10 852 10 DNA Homo sapiens 852 ggaaggacag 10 853 10 DNA Homo sapiens 853 gaagtgtgtc 10 854 10 DNA Homo sapiens 854 gtacccggac 10 855 10 DNA Homo sapiens 855 cctccctgat 10 856 10 DNA Homo sapiens 856 tcatcttcaa 10 857 10 DNA Homo sapiens 857 tcatcttcaa 10 858 10 DNA Homo sapiens 858 tcatcttcaa 10 859 10 DNA Homo sapiens 859 atgtactctg 10 860 10 DNA Homo sapiens 860 cgccggaaca 10 861 10 DNA Homo sapiens 861 aagggagggt 10 862 10 DNA Homo sapiens 862 gaaaaaaaaa 10 863 10 DNA Homo sapiens 863 aaactctgtg 10 864 10 DNA Homo sapiens 864 acacacgcaa 10 865 10 DNA Homo sapiens 865 ccgccgaagt 10 866 10 DNA Homo sapiens 866 tgtgctaaat 10 867 10 DNA Homo sapiens 867 cgaccgtggc 10 868 10 DNA Homo sapiens 868 gcctgggctg 10 869 10 DNA Homo sapiens 869 gcctgggctg 10 870 10 DNA Homo sapiens 870 aaagtcagaa 10 871 10 DNA Homo sapiens 871 tggagcgcta 10 872 10 DNA Homo sapiens 872 gaaatgatga 10 873 10 DNA Homo sapiens 873 tgtcgctggg 10 874 10 DNA Homo sapiens 874 gcccctgcct 10 875 10 DNA Homo sapiens 875 gcccctgcct 10 876 10 DNA Homo sapiens 876 caggcctggc 10 877 10 DNA Homo sapiens 877 caggcctggc 10 878 10 DNA Homo sapiens 878 gcaaaaaaaa 10 879 10 DNA Homo sapiens 879 agccaccacg 10 880 10 DNA Homo sapiens 880 gaggaagaag 10 881 10 DNA Homo sapiens 881 cagctgtagt 10 882 10 DNA Homo sapiens 882 tcttctccct 10 883 10 DNA Homo sapiens 883 tacattctgt 10 884 10 DNA Homo sapiens 884 gggaaacccc 10 885 10 DNA Homo sapiens 885 agccactgca 10 886 10 DNA Homo sapiens 886 tagttgaagt 10 887 10 DNA Homo sapiens 887 gccaagtttg 10 888 10 DNA Homo sapiens 888 ggcggctgca 10 889 10 DNA Homo sapiens 889 aaaaaaaaaa 10 890 10 DNA Homo sapiens 890 aaaaaaaaaa 10 891 10 DNA Homo sapiens 891 aaaaaaaaaa 10 892 10 DNA Homo sapiens 892 aaaaaaaaaa 10 893 10 DNA Homo sapiens 893 tgttccactc 10 894 10 DNA Homo sapiens 894 ctcggtgatg 10 895 10 DNA Homo sapiens 895 cttctcaggg 10 896 10 DNA Homo sapiens 896 ggtagcccac 10 897 10 DNA Homo sapiens 897 gggtttttat 10 898 10 DNA Homo sapiens 898 cctgtaaccc 10 899 10 DNA Homo sapiens 899 gaaacaagat 10 900 10 DNA Homo sapiens 900 gatgagtctc 10 901 10 DNA Homo sapiens 901 ggccctaggc 10 902 10 DNA Homo sapiens 902 tggccccacc 10 903 10 DNA Homo sapiens 903 cagcgcgccc 10 904 10 DNA Homo sapiens 904 aggcgagatc 10 905 10 DNA Homo sapiens 905 gcggggtgga 10 906 10 DNA Homo sapiens 906 ggggccccct 10 907 10 DNA Homo sapiens 907 aaggaacttg 10 908 10 DNA Homo sapiens 908 aaggaacttg 10 909 10 DNA Homo sapiens 909 aattgcaagc 10 910 10 DNA Homo sapiens 910 cctgtgatcc 10 911 10 DNA Homo sapiens 911 ccccgccaag 10 912 10 DNA Homo sapiens 912 ctcaacagca 10 913 10 DNA Homo sapiens 913 aaggtagcag 10 914 10 DNA Homo sapiens 914 aagccagccc 10 915 10 DNA Homo sapiens 915 cagccttgga 10 916 10 DNA Homo sapiens 916 tttgctctcc 10 917 10 DNA Homo sapiens 917 caacattcct 10 918 10 DNA Homo sapiens 918 tactagtcct 10 919 10 DNA Homo sapiens 919 gactctggtg 10 920 10 DNA Homo sapiens 920 gactctggtg 10 921 10 DNA Homo sapiens 921 gtggctcacg 10 922 10 DNA Homo sapiens 922 gtggctcacg 10 923 10 DNA Homo sapiens 923 gtggcgggca 10 924 10 DNA Homo sapiens 924 gtggcgggca 10 925 10 DNA Homo sapiens 925 cctgtggtcc 10 926 10 DNA Homo sapiens 926 tacagcacgg 10 927 10 DNA Homo sapiens 927 gtggcacctg 10 928 10 DNA Homo sapiens 928 tacacgtgag 10 929 10 DNA Homo sapiens 929 tcaggcattt 10 930 10 DNA Homo sapiens 930 ttcacaaagg 10 931 10 DNA Homo sapiens 931 ttcttgtggc 10 932 10 DNA Homo sapiens 932 tccctattag 10 933 10 DNA Homo sapiens 933 tacaagagga 10 934 10 DNA Homo sapiens 934 tcagacgcag 10 935 10 DNA Homo sapiens 935 caggatccag 10 936 10 DNA Homo sapiens 936 tctgtacacc 10 937 10 DNA Homo sapiens 937 gaagcaggac 10 938 10 DNA Homo sapiens 938 gcgccgcccc 10 939 10 DNA Homo sapiens 939 ccctcctggg 10 940 10 DNA Homo sapiens 940 tgggcgcctt 10 941 10 DNA Homo sapiens 941 gtggtacagg 10 942 10 DNA Homo sapiens 942 gtggtacagg 10 943 10 DNA Homo sapiens 943 ggtgagacct 10 944 10 DNA Homo sapiens 944 gagatccgca 10 945 10 DNA Homo sapiens 945 ttggcagccc 10 946 10 DNA Homo sapiens 946 gcctttccct 10 947 10 DNA Homo sapiens 947 ggagtggaca 10 948 10 DNA Homo sapiens 948 ttatggggag 10 949 10 DNA Homo sapiens 949 ttatggggag 10 950 10 DNA Homo sapiens 950 gagtgggggc 10 951 10 DNA Homo sapiens 951 gtggcacgtg 10 952 10 DNA Homo sapiens 952 ctgggcgtgt 10 953 10 DNA Homo sapiens 953 ttggggtttc 10 954 10 DNA Homo sapiens 954 ggctgggcct 10 955 10 DNA Homo sapiens 955 ggctgggcct 10 956 10 DNA Homo sapiens 956 cctgttctcc 10 957 10 DNA Homo sapiens 957 gtgtctcatc 10 958 10 DNA Homo sapiens 958 gtgtctcatc 10 959 10 DNA Homo sapiens 959 acgattgatg 10 960 10 DNA Homo sapiens 960 ttgttgttga 10 961 10 DNA Homo sapiens 961 tggcctcccc 10 962 10 DNA Homo sapiens 962 atcgggcccg 10 963 10 DNA Homo sapiens 963 gccgccatca 10 964 10 DNA Homo sapiens 964 gtgctggacc 10 965 10 DNA Homo sapiens 965 ttgtaatcgt 10 966 10 DNA Homo sapiens 966 taatggtaac 10 967 10 DNA Homo sapiens 967 aacgacctcg 10 968 10 DNA Homo sapiens 968 gcctgcaccc 10 969 10 DNA Homo sapiens 969 gcctgcaccc 10 970 10 DNA Homo sapiens 970 aaggtggagg 10 971 10 DNA Homo sapiens 971 aaggagatgg 10 972 10 DNA Homo sapiens 972 cagttctctg 10 973 10 DNA Homo sapiens 973 gtgaaacctc 10 974 10 DNA Homo sapiens 974 taggttgtct 10 975 10 DNA Homo sapiens 975 cctgtgacag 10 976 10 DNA Homo sapiens 976 ctcataagga 10 977 10 DNA Homo sapiens 977 ggtggctttg 10 978 10 DNA Homo sapiens 978 gctcagctgg 10 979 10 DNA Homo sapiens 979 ggccctgagc 10 980 10 DNA Homo sapiens 980 tctgctaaag 10 981 10 DNA Homo sapiens 981 tctgctaaag 10 982 10 DNA Homo sapiens 982 agccccacaa 10 983 10 DNA Homo sapiens 983 ctgagtctcc 10 984 10 DNA Homo sapiens 984 tgctttggga 10 985 10 DNA Homo sapiens 985 cctgtcctgc 10 986 10 DNA Homo sapiens 986 ggggaaatcg 10 987 10 DNA Homo sapiens 987 tctgcctggg 10 988 10 DNA Homo sapiens 988 caataaactg 10 989 10 DNA Homo sapiens 989 gagtctgagg 10 990 10 DNA Homo sapiens 990 gtggcaggcg 10 991 10 DNA Homo sapiens 991 gtggcaggcg 10 992 10 DNA Homo sapiens 992 cgaggggcca 10 993 10 DNA Homo sapiens 993 gtggggggag 10 994 10 DNA Homo sapiens 994 gagtggctat 10 995 10 DNA Homo sapiens 995 gagtggctat 10 996 10 DNA Homo sapiens 996 gtagactcac 10 997 10 DNA Homo sapiens 997 agggaaagag 10 998 10 DNA Homo sapiens 998 agggaaagag 10 999 10 DNA Homo sapiens 999 cccatcgtcc 10 1000 10 DNA Homo sapiens 1000 tcgccgcgac 10 1001 10 DNA Homo sapiens 1001 tgtcctggtt 10 1002 10 DNA Homo sapiens 1002 ctttttgtgc 10 1003 10 DNA Homo sapiens 1003 ataaattggg 10 1004 10 DNA Homo sapiens 1004 tatcactctg 10 1005 10 DNA Homo sapiens 1005 gtggtgggcg 10 1006 10 DNA Homo sapiens 1006 ccactacact 10 1007 10 DNA Homo sapiens 1007 tgaccccaca 10 1008 10 DNA Homo sapiens 1008 tgatttcact 10 1009 10 DNA Homo sapiens 1009 tgatttcact 10 1010 10 DNA Homo sapiens 1010 ggctcccact 10 1011 10 DNA Homo sapiens 1011 cctgtgtgtg 10 1012 10 DNA Homo sapiens 1012 aatcctgtgg 10 1013 10 DNA Homo sapiens 1013 aggagcaaag 10 1014 10 DNA Homo sapiens 1014 cctttgaaca 10 1015 10 DNA Homo sapiens 1015 gtggggctag 10 1016 10 DNA Homo sapiens 1016 agggtgaaac 10 1017 10 DNA Homo sapiens 1017 cctcaggata 10 1018 10 DNA Homo sapiens 1018 cctcaggata 10 1019 10 DNA Homo sapiens 1019 ttccactaac 10 1020 10 DNA Homo sapiens 1020 cccccgtgaa 10 1021 10 DNA Homo sapiens 1021 tgtgctcggg 10 1022 10 DNA Homo sapiens 1022 aagccttgct 10 1023 10 DNA Homo sapiens 1023 tgttcatcat 10 1024 10 DNA Homo sapiens 1024 aactaacaaa 10 1025 10 DNA Homo sapiens 1025 gctgttgcgc 10 1026 10 DNA Homo sapiens 1026 ggatgtgaaa 10 1027 10 DNA Homo sapiens 1027 actggtacgt 10 1028 10 DNA Homo sapiens 1028 ttgtattcca 10 1029 10 DNA Homo sapiens 1029 ggctgggggc 10 1030 10 DNA Homo sapiens 1030 ccactgcact 10 1031 10 DNA Homo sapiens 1031 ccactgcact 10 1032 10 DNA Homo sapiens 1032 ccactgcact 10 1033 10 DNA Homo sapiens 1033 ccactgcact 10 1034 10 DNA Homo sapiens 1034 ccactgcact 10 1035 10 DNA Homo sapiens 1035 ccactgcact 10 1036 10 DNA Homo sapiens 1036 ccactgcact 10 1037 10 DNA Homo sapiens 1037 ccactgcact 10 1038 10 DNA Homo sapiens 1038 ccactgcact 10 1039 10 DNA Homo sapiens 1039 ccactgcact 10 1040 10 DNA Homo sapiens 1040 ccactgcact 10 1041 10 DNA Homo sapiens 1041 ccactgcact 10 1042 10 DNA Homo sapiens 1042 ccactgcact 10 1043 10 DNA Homo sapiens 1043 ccactgcact 10 1044 10 DNA Homo sapiens 1044 cacttgccct 10 1045 10 DNA Homo sapiens 1045 cacttgccct 10 1046 10 DNA Homo sapiens 1046 gcaagccaac 10 1047 10 DNA Homo sapiens 1047 tagataatgg 10 1048 10 DNA Homo sapiens 1048 tcgaagcccc 10 1049 10 DNA Homo sapiens 1049 agaaaaaaaa 10 1050 10 DNA Homo sapiens 1050 agaaaaaaaa 10 1051 10 DNA Homo sapiens 1051 ggcgcctcct 10 1052 10 DNA Homo sapiens 1052 ggcgcctcct 10 1053 10 DNA Homo sapiens 1053 taaactgttt 10 1054 10 DNA Homo sapiens 1054 taaactgttt 10 1055 10 DNA Homo sapiens 1055 ggcctttttt 10 1056 10 DNA Homo sapiens 1056 ggcctttttt 10 1057 10 DNA Homo sapiens 1057 gcgacagctc 10 1058 10 DNA Homo sapiens 1058 cccacactac 10 1059 10 DNA Homo sapiens 1059 agcagatcag 10 1060 10 DNA Homo sapiens 1060 gcataggctg 10 1061 10 DNA Homo sapiens 1061 gaggccgacc 10 1062 10 DNA Homo sapiens 1062 aaatgccaca 10 1063 10 DNA Homo sapiens 1063 agccctacaa 10 1064 10 DNA Homo sapiens 1064 ttggtgaagg 10 1065 10 DNA Homo sapiens 1065 ccgggcccag 10 1066 10 DNA Homo sapiens 1066 ttcatacacc 10 1067 10 DNA Homo sapiens 1067 gcagccatcc 10 1068 10 DNA Homo sapiens 1068 gccgggtggg 10 1069 10 DNA Homo sapiens 1069 gctcccagac 10 1070 10 DNA Homo sapiens 1070 agccaccgtg 10 1071 10 DNA Homo sapiens 1071 tcagctggcc 10 1072 10 DNA Homo sapiens 1072 gggggcgcct 10 1073 10 DNA Homo sapiens 1073 cggcccaacg 10 1074 10 DNA Homo sapiens 1074 tggccatctg 10 1075 10 DNA Homo sapiens 1075 cctcccccgt 10 1076 10 DNA Homo sapiens 1076 acttgttcgc 10 1077 10 DNA Homo sapiens 1077 aagactggct 10 1078 10 DNA Homo sapiens 1078 agcacatttg 10 1079 10 DNA Homo sapiens 1079 gtgaaggcag 10 1080 10 DNA Homo sapiens 1080 caataaatgt 10 1081 10 DNA Homo sapiens 1081 gccagggcgg 10 1082 10 DNA Homo sapiens 1082 gtgtaataag 10 1083 10 DNA Homo sapiens 1083 ttctgcactg 10 1084 10 DNA Homo sapiens 1084 ttctgcactg 10 1085 10 DNA Homo sapiens 1085 gtgaaacccc 10 1086 10 DNA Homo sapiens 1086 gtgaaacccc 10 1087 10 DNA Homo sapiens 1087 gtgaaacccc 10 1088 10 DNA Homo sapiens 1088 gtgaaacccc 10 1089 10 DNA Homo sapiens 1089 gtgaaacccc 10 1090 10 DNA Homo sapiens 1090 gtgaaacccc 10 1091 10 DNA Homo sapiens 1091 gtgaaacccc 10 1092 10 DNA Homo sapiens 1092 gtgaaacccc 10 1093 10 DNA Homo sapiens 1093 gtgaaacccc 10 1094 10 DNA Homo sapiens 1094 gtgaaacccc 10 1095 10 DNA Homo sapiens 1095 gtgaaacccc 10 1096 10 DNA Homo sapiens 1096 gtgaaacccc 10 1097 10 DNA Homo sapiens 1097 gtgaaacccc 10 1098 10 DNA Homo sapiens 1098 gtgaaacccc 10 1099 10 DNA Homo sapiens 1099 gtgaaacccc 10 1100 10 DNA Homo sapiens 1100 gacacctcct 10 1101 10 DNA Homo sapiens 1101 gacgtgtggg 10 1102 10 DNA Homo sapiens 1102 gcaaaacccc 10 1103 10 DNA Homo sapiens 1103 taccagtgta 10 1104 10 DNA Homo sapiens 1104 cccctcccca 10 1105 10 DNA Homo sapiens 1105 ggtgatgagg 10 1106 10 DNA Homo sapiens 1106 gtgtgtaaaa 10 1107 10 DNA Homo sapiens 1107 ggctcctcga 10 1108 10 DNA Homo sapiens 1108 aaaagaaact 10 1109 10 DNA Homo sapiens 1109 cagcgcacag 10 1110 10 DNA Homo sapiens 1110 ctgggagagg 10 1111 10 DNA Homo sapiens 1111 gaaaaatggt 10 1112 10 DNA Homo sapiens 1112 atcacgccct 10 1113 10 DNA Homo sapiens 1113 tagctctatg 10 1114 10 DNA Homo sapiens 1114 gtattggcct 10 1115 10 DNA Homo sapiens 1115 cccgacgtgc 10 1116 10 DNA Homo sapiens 1116 gaagttatga 10 1117 10 DNA Homo sapiens 1117 taaaaaaaaa 10 1118 10 DNA Homo sapiens 1118 taaaaaaaaa 10 1119 10 DNA Homo sapiens 1119 taaaaaaaaa 10 1120 10 DNA Homo sapiens 1120 gccgccctgc 10 1121 10 DNA Homo sapiens 1121 tttggggctg 10 1122 10 DNA Homo sapiens 1122 gtggcaggca 10 1123 10 DNA Homo sapiens 1123 ggctgtaccc 10 1124 10 DNA Homo sapiens 1124 agcagggctc 10 1125 10 DNA Homo sapiens 1125 aagaagatag 10 1126 10 DNA Homo sapiens 1126 tctggggacg 10 1127 10 DNA Homo sapiens 1127 gctaggttta 10 1128 10 DNA Homo sapiens 1128 tggtgacagt 10 1129 10 DNA Homo sapiens 1129 ttaccatatc 10 1130 10 DNA Homo sapiens 1130 gtggcgggtg 10 1131 10 DNA Homo sapiens 1131 tggatcctag 10 1132 10 DNA Homo sapiens 1132 gggtttgaac 10 1133 10 DNA Homo sapiens 1133 aatgcaggca 10 1134 10 DNA Homo sapiens 1134 acatcgtagg 10 1135 10 DNA Homo sapiens 1135 aacgctgcct 10 1136 10 DNA Homo sapiens 1136 tggaggtggg 10 1137 10 DNA Homo sapiens 1137 tgcctgctcc 10 1138 10 DNA Homo sapiens 1138 cttccagcta 10 1139 10 DNA Homo sapiens 1139 gtaagtgtac 10 1140 10 DNA Homo sapiens 1140 gtaagtgtac 10 1141 10 DNA Homo sapiens 1141 gtgtctcgca 10 1142 10 DNA Homo sapiens 1142 atccggcgcc 10 1143 10 DNA Homo sapiens 1143 tgcctgcacc 10 1144 10 DNA Homo sapiens 1144 ttcctattaa 10 1145 10 DNA Homo sapiens 1145 caggagttca 10 1146 10 DNA Homo sapiens 1146 gtctgcgtgc 10 1147 10 DNA Homo sapiens 1147 gaaatacagt 10 1148 10 DNA Homo sapiens 1148 gaaatacagt 10 1149 10 DNA Homo sapiens 1149 tgagcccggc 10 1150 10 DNA Homo sapiens 1150 gtggtgtgtg 10 1151 10 DNA Homo sapiens 1151 gtggtgtgtg 10 1152 10 DNA Homo sapiens 1152 tcacccacac 10 1153 10 DNA Homo sapiens 1153 tcacccacac 10 1154 10 DNA Homo sapiens 1154 ctggatctgg 10 1155 10 DNA Homo sapiens 1155 gaagatgtgt 10 1156 10 DNA Homo sapiens 1156 cggataacca 10 1157 10 DNA Homo sapiens 1157 tcagaaggtg 10 1158 10 DNA Homo sapiens 1158 gagaaacccc 10 1159 10 DNA Homo sapiens 1159 gagaaacccc 10 1160 10 DNA Homo sapiens 1160 gagaaacccc 10 1161 10 DNA Homo sapiens 1161 ctcgttaaga 10 1162 10 DNA Homo sapiens 1162 ttggagatct 10 1163 10 DNA Homo sapiens 1163 gaggtccctg 10 1164 10 DNA Homo sapiens 1164 ttccgcgtgc 10 1165 10 DNA Homo sapiens 1165 cagcccaacc 10 1166 10 DNA Homo sapiens 1166 gtggctcaca 10 1167 10 DNA Homo sapiens 1167 tagaaaggca 10 1168 10 DNA Homo sapiens 1168 taagtagcaa 10 1169 10 DNA Homo sapiens 1169 ggtgagacac 10 1170 10 DNA Homo sapiens 1170 cccatcgtct 10 1171 10 DNA Homo sapiens 1171 ccgatcaccg 10 1172 10 DNA Homo sapiens 1172 gaatcggtta 10 1173 10 DNA Homo sapiens 1173 aacccaggag 10 1174 10 DNA Homo sapiens 1174 ttttgaagca 10 1175 10 DNA Homo sapiens 1175 cacaggcaaa 10 1176 10 DNA Homo sapiens 1176 tcagcttcac 10 1177 10 DNA Homo sapiens 1177 tcagcttcac 10 1178 10 DNA Homo sapiens 1178 gagggccggt 10 1179 10 DNA Homo sapiens 1179 ccccagccag 10 1180 10 DNA Homo sapiens 1180 gtggtgggtg 10 1181 10 DNA Homo sapiens 1181 ctgccaagtt 10 1182 10 DNA Homo sapiens 1182 gagaaaccct 10 1183 10 DNA Homo sapiens 1183 gagaaaccct 10 1184 10 DNA Homo sapiens 1184 actaacaccc 10 1185 10 DNA Homo sapiens 1185 ttttgggggc 10 1186 10 DNA Homo sapiens 1186 ttttgggggc 10 1187 10 DNA Homo sapiens 1187 gtgaaaccca 10 1188 10 DNA Homo sapiens 1188 gctttcattg 10 1189 10 DNA Homo sapiens 1189 gtggcacgca 10 1190 10 DNA Homo sapiens 1190 gggtcaaaag 10 1191 10 DNA Homo sapiens 1191 gggggtcacc 10 1192 10 DNA Homo sapiens 1192 gtgaaaccct 10 1193 10 DNA Homo sapiens 1193 gtgaaaccct 10 1194 10 DNA Homo sapiens 1194 gtgaaaccct 10 1195 10 DNA Homo sapiens 1195 gtgaaaccct 10 1196 10 DNA Homo sapiens 1196 gtgaaaccct 10 1197 10 DNA Homo sapiens 1197 gtgaaaccct 10 1198 10 DNA Homo sapiens 1198 agttgaaatt 10 1199 10 DNA Homo sapiens 1199 agaatcgctt 10 1200 10 DNA Homo sapiens 1200 aggtcaagag 10 1201 10 DNA Homo sapiens 1201 ctaaccagac 10 1202 10 DNA Homo sapiens 1202 gggatggcag 10 1203 10 DNA Homo sapiens 1203 agacccacaa 10 1204 10 DNA Homo sapiens 1204 tcgaagaacc 10 1205 10 DNA Homo sapiens 1205 tgaaataaaa 10 1206 10 DNA Homo sapiens 1206 actgaggtgc 10 1207 10 DNA Homo sapiens 1207 actcagaaga 10 1208 10 DNA Homo sapiens 1208 gaacacatcc 10 1209 10 DNA Homo sapiens 1209 aactaatact 10 1210 10 DNA Homo sapiens 1210 agatgtgtgg 10 1211 10 DNA Homo sapiens 1211 gtggtgtgca 10 1212 10 DNA Homo sapiens 1212 ggcgtcctgg 10 1213 10 DNA Homo sapiens 1213 cctgcaatcc 10 1214 10 DNA Homo sapiens 1214 gcctggccat 10 1215 10 DNA Homo sapiens 1215 gcctggccat 10 1216 10 DNA Homo sapiens 1216 gctgcccttg 10 1217 10 DNA Homo sapiens 1217 gctgcccttg 10 1218 10 DNA Homo sapiens 1218 gccagcccag 10 1219 10 DNA Homo sapiens 1219 tcctattaag 10 1220 10 DNA Homo sapiens 1220 attgtgccac 10 1221 10 DNA Homo sapiens 1221 ccattgcact 10 1222 10 DNA Homo sapiens 1222 gcacctcagc 10 1223 10 DNA Homo sapiens 1223 ttggtcaggc 10 1224 10 DNA Homo sapiens 1224 ttggtcaggc 10 1225 10 DNA Homo sapiens 1225 gggccccgca 10 1226 10 DNA Homo sapiens 1226 gtggcacaca 10 1227 10 DNA Homo sapiens 1227 gtggcacaca 10 1228 10 DNA Homo sapiens 1228 ttggccaggc 10 1229 10 DNA Homo sapiens 1229 ttggccaggc 10 1230 10 DNA Homo sapiens 1230 ttggccaggc 10 1231 10 DNA Homo sapiens 1231 ttggccaggc 10 1232 10 DNA Homo sapiens 1232 ttggccaggc 10 1233 10 DNA Homo sapiens 1233 ttggccaggc 10 1234 10 DNA Homo sapiens 1234 ttggccaggc 10 1235 10 DNA Homo sapiens 1235 gtcactgcct 10 1236 10 DNA Homo sapiens 1236 gccaccccgt 10 1237 10 DNA Homo sapiens 1237 tccctataag 10 1238 10 DNA Homo sapiens 1238 cctgtaatcc 10 1239 10 DNA Homo sapiens 1239 cctgtaatcc 10 1240 10 DNA Homo sapiens 1240 cctgtaatcc 10 1241 10 DNA Homo sapiens 1241 cctgtaatcc 10 1242 10 DNA Homo sapiens 1242 cctgtaatcc 10 1243 10 DNA Homo sapiens 1243 cctgtaatcc 10 1244 10 DNA Homo sapiens 1244 cctgtaatcc 10 1245 10 DNA Homo sapiens 1245 cctgtaatcc 10 1246 10 DNA Homo sapiens 1246 cctgtaatcc 10 1247 10 DNA Homo sapiens 1247 cctgtaatcc 10 1248 10 DNA Homo sapiens 1248 cctgtaatcc 10 1249 10 DNA Homo sapiens 1249 cctgtaatcc 10 1250 10 DNA Homo sapiens 1250 cctgtaatcc 10 1251 10 DNA Homo sapiens 1251 cctgtaatcc 10 1252 10 DNA Homo sapiens 1252 cctgtaatcc 10 1253 10 DNA Homo sapiens 1253 cctgtaatcc 10 1254 10 DNA Homo sapiens 1254 cctgtaatcc 10 1255 10 DNA Homo sapiens 1255 cctgtaatcc 10 1256 10 DNA Homo sapiens 1256 cctgtaatcc 10 1257 10 DNA Homo sapiens 1257 tccccgtaca 10 1258 10 DNA Homo sapiens 1258 gtcacaccac 10 1259 10 DNA Homo sapiens 1259 gtcacaccac 10 1260 10 DNA Homo sapiens 1260 atggcaaggg 10 1261 10 DNA Homo sapiens 1261 ctgttggcat 10 1262 10 DNA Homo sapiens 1262 ctagcctcac 10 1263 10 DNA Homo sapiens 1263 agtgcaagac 10 1264 10 DNA Homo sapiens 1264 cctgtagtcc 10 1265 10 DNA Homo sapiens 1265 ttttctgaaa 10 1266 10 DNA Homo sapiens 1266 ctcccctgcc 10 1267 10 DNA Homo sapiens 1267 tctctttttc 10 1268 10 DNA Homo sapiens 1268 gcggacgagg 10 1269 10 DNA Homo sapiens 1269 gcggacgagg 10 1270 10 DNA Homo sapiens 1270 ggagtcattg 10 1271 10 DNA Homo sapiens 1271 gtagcaggtg 10 1272 10 DNA Homo sapiens 1272 cgcaagctgg 10 1273 10 DNA Homo sapiens 1273 gtgaaacccg 10 1274 10 DNA Homo sapiens 1274 aggtcaggag 10 1275 10 DNA Homo sapiens 1275 aggtcaggag 10 1276 10 DNA Homo sapiens 1276 aggtcaggag 10 1277 10 DNA Homo sapiens 1277 gaatgcagtt 10 1278 10 DNA Homo sapiens 1278 gaatgcagtt 10 1279 10 DNA Homo sapiens 1279 gaatgcagtt 10 1280 10 DNA Homo sapiens 1280 gtgagcccat 10 1281 10 DNA Homo sapiens 1281 gtaatcctgc 10 1282 10 DNA Homo sapiens 1282 tgaagtaaca 10 1283 10 DNA Homo sapiens 1283 tgcctgtaat 10 1284 10 DNA Homo sapiens 1284 gtagcataaa 10 1285 10 DNA Homo sapiens 1285 ccgtggtcgt 10 1286 10 DNA Homo sapiens 1286 atgaaacccc 10 1287 10 DNA Homo sapiens 1287 aagattggtg 10 1288 10 DNA Homo sapiens 1288 atccgtgccc 10 1289 10 DNA Homo sapiens 1289 cccttcactg 10 1290 10 DNA Homo sapiens 1290 cccttcactg 10 1291 10 DNA Homo sapiens 1291 cagctggggc 10 1292 10 DNA Homo sapiens 1292 caggccccac 10 1293 10 DNA Homo sapiens 1293 tgtttatcct 10 1294 10 DNA Homo sapiens 1294 taaccaatca 10 1295 10 DNA Homo sapiens 1295 cacctgtagt 10 1296 10 DNA Homo sapiens 1296 taccctaaaa 10 1297 10 DNA Homo sapiens 1297 taccctaaaa 10 1298 10 DNA Homo sapiens 1298 taccctaaaa 10 1299 10 DNA Homo sapiens 1299 tgcctctgcg 10 1300 10 DNA Homo sapiens 1300 gcaaaaccct 10 1301 10 DNA Homo sapiens 1301 aaggaccttt 10 1302 10 DNA Homo sapiens 1302 ctggcgccga 10 1303 10 DNA Homo sapiens 1303 gaagctttgc 10 1304 10 DNA Homo sapiens 1304 gctccgagcg 10 1305 10 DNA Homo sapiens 1305 ttgcccaggc 10 1306 10 DNA Homo sapiens 1306 ttgcccaggc 10 1307 10 DNA Homo sapiens 1307 acccacgtca 10 1308 10 DNA Homo sapiens 1308 gctccactgg 10 1309 10 DNA Homo sapiens 1309 tttaacggcc 10 1310 10 DNA Homo sapiens 1310 cttgtaatcc 10 1311 10 DNA Homo sapiens 1311 cacttttggg 10 1312 10 DNA Homo sapiens 1312 ccgggtgatg 10 1313 10 DNA Homo sapiens 1313 ggggtaagaa 10 1314 10 DNA Homo sapiens 1314 tgactggcag 10 1315 10 DNA Homo sapiens 1315 caatgtgtta 10 1316 10 DNA Homo sapiens 1316 ggctcgggat 10 1317 10 DNA Homo sapiens 1317 tgcctgtagt 10 1318 10 DNA Homo sapiens 1318 cgccgccggc 10 1319 10 DNA Homo sapiens 1319 ggtggggaga 10 1320 10 DNA Homo sapiens 1320 gtaaaaccct 10 1321 10 DNA Homo sapiens 1321 ggctcctggc 10 1322 10 DNA Homo sapiens 1322 agtaggtggc 10 1323 10 DNA Homo sapiens 1323 ggaggtgggg 10 1324 10 DNA Homo sapiens 1324 cctttggcta 10 1325 10 DNA Homo sapiens 1325 agaaagatgt 10 1326 10 DNA Homo sapiens 1326 agaacaaaac 10 1327 10 DNA Homo sapiens 1327 aactaaaaaa 10 1328 10 DNA Homo sapiens 1328 attgcaccac 10 1329 10 DNA Homo sapiens 1329 gatcccaact 10 1330 10 DNA Homo sapiens 1330 gatcccaact 10 1331 10 DNA Homo sapiens 1331 cactactcac 10 1332 10 DNA Homo sapiens 1332 ctgtacagac 10 1333 10 DNA Homo sapiens 1333 taccctagaa 10 1334 10 DNA Homo sapiens 1334 gtaaaacccc 10 1335 10 DNA Homo sapiens 1335 gtaaaacccc 10 1336 10 DNA Homo sapiens 1336 gtaaaacccc 10 1337 10 DNA Homo sapiens 1337 ctgagagctg 10 1338 10 DNA Homo sapiens 1338 ggctggtctg 10 1339 10 DNA Homo sapiens 1339 acgcagggag 10 1340 10 DNA Homo sapiens 1340 gccctcggcc 10 1341 10 DNA Homo sapiens 1341 ctcccttgcc 10 1342 10 DNA Homo sapiens 1342 cctgtaatct 10 1343 10 DNA Homo sapiens 1343 aggtcctagc 10 1344 10 DNA Homo sapiens 1344 actgaaggcg 10 1345 10 DNA Homo sapiens 1345 aaggaagatg 10 1346 10 DNA Homo sapiens 1346 ccgacgggcg 10 1347 10 DNA Homo sapiens 1347 gcccccaata 10 1348 10 DNA Homo sapiens 1348 aggatgtggg 10 1349 10 DNA Homo sapiens 1349 ggaggccgag 10 1350 10 DNA Homo sapiens 1350 acccccccgc 10 1351 10 DNA Homo sapiens 1351 ctggcctgtg 10 1352 10 DNA Homo sapiens 1352 ctggcctgtg 10 1353 10 DNA Homo sapiens 1353 ctggcctgtg 10 1354 10 DNA Homo sapiens 1354 cacccccagg 10 1355 10 DNA Homo sapiens 1355 cacccccagg 10 1356 10 DNA Homo sapiens 1356 gtgaaactcc 10 1357 10 DNA Homo sapiens 1357 gtgaaactcc 10 1358 10 DNA Homo sapiens 1358 agaattgctt 10 1359 10 DNA Homo sapiens 1359 agaattgctt 10 1360 10 DNA Homo sapiens 1360 atggcctcct 10 1361 10 DNA Homo sapiens 1361 aactgtcctt 10 1362 10 DNA Homo sapiens 1362 aaggaatcgg 10 1363 10 DNA Homo sapiens 1363 tctgtttatc 10 1364 10 DNA Homo sapiens 1364 actttttcaa 10 1365 10 DNA Homo sapiens 1365 tctgtaatcc 10 1366 10 DNA Homo sapiens 1366 tctgtaatcc 10 1367 10 DNA Homo sapiens 1367 gtgaaaaccc 10 1368 10 DNA Homo sapiens 1368 ggcaggcaca 10 1369 10 DNA Homo sapiens 1369 ggggcagggc 10 1370 10 DNA Homo sapiens 1370 ggggcagggc 10 1371 10 DNA Homo sapiens 1371 gtgaaactct 10 1372 10 DNA Homo sapiens 1372 tggaccaggc 10 1373 10 DNA Homo sapiens 1373 cctataatcc 10 1374 10 DNA Homo sapiens 1374 cctataatcc 10 1375 10 DNA Homo sapiens 1375 cctataatcc 10 1376 10 DNA Homo sapiens 1376 aactgcttca 10 1377 10 DNA Homo sapiens 1377 ggattgtctg 10 1378 10 DNA Homo sapiens 1378 cctgtaattc 10 1379 10 DNA Homo sapiens 1379 ctgggcctgg 10 1380 10 DNA Homo sapiens 1380 acccttggcc 10 1381 10 DNA Homo sapiens 1381 atggcgatct 10 1382 10 DNA Homo sapiens 1382 ttgtctgcct 10 1383 10 DNA Homo sapiens 1383 tgaatctggg 10 1384 10 DNA Homo sapiens 1384 agcctttgtt 10 1385 10 DNA Homo sapiens 1385 cttttcagca 10 1386 10 DNA Homo sapiens 1386 cctggagtgg 10 1387 10 DNA Homo sapiens 1387 cggagaccct 10 1388 10 DNA Homo sapiens 1388 ccctgggttc 10 1389 10 DNA Homo sapiens 1389 atttgagaag 10 1390 10 DNA Homo sapiens 1390 acaactcaat 10 1391 10 DNA Homo sapiens 1391 cttgattccc 10 1392 10 DNA Homo sapiens 1392 ggctggtctc 10 1393 10 DNA Homo sapiens 1393 aggtggcaag 10 1394 10 DNA Homo sapiens 1394 ctagctttta 10 1395 10 DNA Homo sapiens 1395 tcaccggtca 10 1396 10 DNA Homo sapiens 1396 ggccgcgttc 10 1397 10 DNA Homo sapiens 1397 gagagctccc 10 1398 10 DNA Homo sapiens 1398 gagagctccc 10 1399 10 DNA Homo sapiens 1399 gagagctccc 10 1400 10 DNA Homo sapiens 1400 gagagctccc 10 1401 10 DNA Homo sapiens 1401 ccccgtacat 10 1402 10 DNA Homo sapiens 1402 tggcgtacgg 10 1403 10 DNA Homo sapiens 1403 tccccgacat 10 1404 10 DNA Homo sapiens 1404 cctggctaat 10 1405 10 DNA Homo sapiens 1405 tcacagctgt 10 1406 10 DNA Homo sapiens 1406 tcccattaag 10 1407 10 DNA Homo sapiens 1407 gtgcactgag 10 1408 10 DNA Homo sapiens 1408 gtgcactgag 10 1409 10 DNA Homo sapiens 1409 gcttaccttt 10 1410 10 DNA Homo sapiens 1410 ctggcccgga 10 1411 10 DNA Homo sapiens 1411 ctggcccgga 10 1412 10 DNA Homo sapiens 1412 gggcctgtgc 10 1413 10 DNA Homo sapiens 1413 gggcctgtgc 10 1414 10 DNA Homo sapiens 1414 gcccctccgg 10 1415 10 DNA Homo sapiens 1415 ttgtgatgta 10 1416 10 DNA Homo sapiens 1416 ttgtgatgta 10 1417 10 DNA Homo sapiens 1417 catcttcacc 10 1418 10 DNA Homo sapiens 1418 ttggccagga 10 1419 10 DNA Homo sapiens 1419 agaatcactt 10 1420 10 DNA Homo sapiens 1420 ttagccagga 10 1421 10 DNA Homo sapiens 1421 gttgtggtta 10 1422 10 DNA Homo sapiens 1422 caagcatccc 10 1423 10 DNA Homo sapiens 1423 gacatatgta 10 1424 10 DNA Homo sapiens 1424 agtatctggg 10 1425 10 DNA Homo sapiens 1425 accgcctgtg 10 1426 10 DNA Homo sapiens 1426 ctcttcgaga 10 1427 10 DNA Homo sapiens 1427 atgagctgac 10 1428 10 DNA Homo sapiens 1428 gcctctgtct 10 1429 10 DNA Homo sapiens 1429 aaggaagatc 10 1430 10 DNA Homo sapiens 1430 aaaacattct 10 1431 10 DNA Homo sapiens 1431 ctcagacagt 10 1432 10 DNA Homo sapiens 1432 cccaagctag 10 1433 10 DNA Homo sapiens 1433 cccaagctag 10 1434 10 DNA Homo sapiens 1434 tcaatcaaga 10 1435 10 DNA Homo sapiens 1435 tgcagcgcct 10 1436 10 DNA Homo sapiens 1436 ttcactgtga 10 1437 10 DNA Homo sapiens 1437 ctgacctgtg 10 1438 10 DNA Homo sapiens 1438 ggggtcaggg 10 1439 10 DNA Homo sapiens 1439 ggctttaggg 10 1440 10 DNA Homo sapiens 1440 tgggtgagcc 10 1441 10 DNA Homo sapiens 1441 agggtgtttt 10 1442 10 DNA Homo sapiens 1442 agggtgtttt 10 1443 10 DNA Homo sapiens 1443 tggtgtatgc 10 1444 10 DNA Homo sapiens 1444 gagtagagaa 10 1445 10 DNA Homo sapiens 1445 tgcaggcctg 10 1446 10 DNA Homo sapiens 1446 gcgaaaccct 10 1447 10 DNA Homo sapiens 1447 gtgaccacgg 10 1448 10 DNA Homo sapiens 1448 gtgaccacgg 10 1449 10 DNA Homo sapiens 1449 cccatcgtcc 10 1450 10 DNA Homo sapiens 1450 tgtgttgaga 10 1451 10 DNA Homo sapiens 1451 ggatttggcc 10 1452 10 DNA Homo sapiens 1452 cccgtccgga 10 1453 10 DNA Homo sapiens 1453 atggctggta 10 1454 10 DNA Homo sapiens 1454 gtgaaacccc 10 1455 10 DNA Homo sapiens 1455 cctccagcta 10 1456 10 DNA Homo sapiens 1456 ttggtcctct 10 1457 10 DNA Homo sapiens 1457 tgatttcact 10 1458 10 DNA Homo sapiens 1458 cctgtaatcc 10 1459 10 DNA Homo sapiens 1459 actttttcaa 10 1460 10 DNA Homo sapiens 1460 aaaaaaaaaa 10 1461 10 DNA Homo sapiens 1461 gagggagttt 10 1462 10 DNA Homo sapiens 1462 gccgaggaag 10 1463 10 DNA Homo sapiens 1463 cacctaattg 10 1464 10 DNA Homo sapiens 1464 cgccgccggc 10 1465 10 DNA Homo sapiens 1465 ggggaaatcg 10 1466 10 DNA Homo sapiens 1466 gaaaaatggt 10 1467 10 DNA Homo sapiens 1467 gggctggggt 10 1468 10 DNA Homo sapiens 1468 gccgggtggg 10 1469 10 DNA Homo sapiens 1469 agccctacaa 10 1470 10 DNA Homo sapiens 1470 ctgggttaat 10 1471 10 DNA Homo sapiens 1471 caaaccatcc 10 1472 10 DNA Homo sapiens 1472 tgcacgtttt 10 1473 10 DNA Homo sapiens 1473 aggctacgga 10 1474 10 DNA Homo sapiens 1474 gcagccatcc 10 1475 10 DNA Homo sapiens 1475 ttcaataaaa 10 1476 10 DNA Homo sapiens 1476 ctaagacttc 10 1477 10 DNA Homo sapiens 1477 tggtgttgag 10 1478 10 DNA Homo sapiens 1478 taccatcaat 10 1479 10 DNA Homo sapiens 1479 ttcatacacc 10 1480 10 DNA Homo sapiens 1480 ccactgcact 10 1481 10 DNA Homo sapiens 1481 actaacaccc 10 1482 10 DNA Homo sapiens 1482 aaggtggagg 10 1483 10 DNA Homo sapiens 1483 agcacctcca 10 1484 10 DNA Homo sapiens 1484 cacaaacggt 10 1485 10 DNA Homo sapiens 1485 aggaaagctg 10 1486 10 DNA Homo sapiens 1486 gtgaaaccct 10 1487 10 DNA Homo sapiens 1487 aatcctgtgg 10 1488 10 DNA Homo sapiens 1488 ttggggtttc 10 1489 10 DNA Homo sapiens 1489 aagacagtgg 10 1490 10 DNA Homo sapiens 1490 atttgagaag 10 1491 10 DNA Homo sapiens 1491 gccgtgtccg 10 1492 10 DNA Homo sapiens 1492 cgccggaaca 10 1493 10 DNA Homo sapiens 1493 tctccatacc 10 1494 10 DNA Homo sapiens 1494 acatcatcga 10 1495 10 DNA Homo sapiens 1495 aacgcggcca 10 1496 10 DNA Homo sapiens 1496 agggcttcca 10 1497 10 DNA Homo sapiens 1497 ccgtccaagg 10 1498 10 DNA Homo sapiens 1498 cgctggttcc 10 1499 10 DNA Homo sapiens 1499 ctcaacatct 10 1500 10 DNA Homo sapiens 1500 actccaaaaa 10 1501 10 DNA Homo sapiens 1501 cctagctgga 10 1502 10 DNA Homo sapiens 1502 gtgaaggcag 10 1503 10 DNA Homo sapiens 1503 agctctccct 10 1504 10 DNA Homo sapiens 1504 taggttgtct 10 1505 10 DNA Homo sapiens 1505 ggaccactga 10 1506 10 DNA Homo sapiens 1506 aaggagatgg 10 1507 10 DNA Homo sapiens 1507 aactaaaaaa 10 1508 10 DNA Homo sapiens 1508 ggctgggggc 10 1509 10 DNA Homo sapiens 1509 ccagaacaga 10 1510 10 DNA Homo sapiens 1510 cccatcgtcc 10 1511 10 DNA Homo sapiens 1511 gtgaccacgg 10 1512 10 DNA Homo sapiens 1512 tgtgttgaga 10 1513 10 DNA Homo sapiens 1513 gtgaaacccc 10 1514 10 DNA Homo sapiens 1514 cctgtaatcc 10 1515 10 DNA Homo sapiens 1515 ctaagacttc 10 1516 10 DNA Homo sapiens 1516 cacctaattg 10 1517 10 DNA Homo sapiens 1517 cccgtccgga 10 1518 10 DNA Homo sapiens 1518 ttggtcctct 10 1519 10 DNA Homo sapiens 1519 atggctggta 10 1520 10 DNA Homo sapiens 1520 ttggggtttc 10 1521 10 DNA Homo sapiens 1521 ccactgcact 10 1522 10 DNA Homo sapiens 1522 tgatttcact 10 1523 10 DNA Homo sapiens 1523 actttttcaa 10 1524 10 DNA Homo sapiens 1524 gcagccatcc 10 1525 10 DNA Homo sapiens 1525 taccatcaat 10 1526 10 DNA Homo sapiens 1526 ggatttggcc 10 1527 10 DNA Homo sapiens 1527 ccctgggttc 10 1528 10 DNA Homo sapiens 1528 gccgaggaag 10 1529 10 DNA Homo sapiens 1529 aggctacgga 10 1530 10 DNA Homo sapiens 1530 cgccgccggc 10 1531 10 DNA Homo sapiens 1531 ttcatacacc 10 1532 10 DNA Homo sapiens 1532 agccctacaa 10 1533 10 DNA Homo sapiens 1533 cacaaacggt 10 1534 10 DNA Homo sapiens 1534 aaggtggagg 10 1535 10 DNA Homo sapiens 1535 cttccttgcc 10 1536 10 DNA Homo sapiens 1536 tggtgttgag 10 1537 10 DNA Homo sapiens 1537 gtgaaaccct 10 1538 10 DNA Homo sapiens 1538 ggggaaatcg 10 1539 10 DNA Homo sapiens 1539 agcacctcca 10 1540 10 DNA Homo sapiens 1540 cctccagcta 10 1541 10 DNA Homo sapiens 1541 aagacagtgg 10 1542 10 DNA Homo sapiens 1542 ctgggttaat 10 1543 10 DNA Homo sapiens 1543 atttgagaag 10 1544 10 DNA Homo sapiens 1544 gccgggtggg 10 1545 10 DNA Homo sapiens 1545 gggctggggt 10 1546 10 DNA Homo sapiens 1546 agggcttcca 10 1547 10 DNA Homo sapiens 1547 aaaaaaaaaa 10 1548 10 DNA Homo sapiens 1548 gagggagttt 10 1549 10 DNA Homo sapiens 1549 gcgaccgtca 10 1550 10 DNA Homo sapiens 1550 actaacaccc 10 1551 10 DNA Homo sapiens 1551 cgccggaaca 10 1552 10 DNA Homo sapiens 1552 tgggcaaagc 10 1553 10 DNA Homo sapiens 1553 tgcacgtttt 10 1554 10 DNA Homo sapiens 1554 aatcctgtgg 10 1555 10 DNA Homo sapiens 1555 caagcatccc 10 1556 10 DNA Homo sapiens 1556 ccgtccaagg 10 1557 10 DNA Homo sapiens 1557 taggttgtct 10 1558 10 DNA Homo sapiens 1558 gccgtgtccg 10 1559 10 DNA Homo sapiens 1559 gctttatttg 10 1560 10 DNA Homo sapiens 1560 ctagcctcac 10 1561 10 DNA Homo sapiens 1561 cctagctgga 10 1562 10 DNA Homo sapiens 1562 gcccctgctg 10 1563 10 DNA Homo sapiens 1563 acccttggcc 10 1564 10 DNA Homo sapiens 1564 aggaaagctg 10 

1. A method of identifying a test cell as a cancer cell, comprising the steps of: determining expression in a test cell of a gene product of an AXL receptor tyrosine kinase gene comprising a nucleotide sequence shown in SEQ ID NO:240, wherein the test cell is a cell type selected from the group consisting of a colon epithelial cell, a lung epithelial cell, a melanocyte, and a brain cell; identifying the test cell as a cancer cell if an increase in said expression of at least two-fold relative to expression of the gene in a normal cell of said type is observed.
 2. The method of claim 1 wherein the gene product is RNA.
 3. The method of claim 2 wherein expression is determined using at least one oligonucleotide probe.
 4. The method of claim 3 wherein expression is determined using at least two oligonucleotide probes.
 5. The method of claim 3 wherein the at least one oligonucleotide probe is immobilized on a solid support.
 6. The method of claim 5 wherein the at least one oligonucleotide probe is in an array.
 7. The method of claim 1 wherein the test cell is a colon epithelial cell.
 8. The method of claim 1 wherein the test cell is a lung epithelial cell.
 9. The method of claim 1 wherein the test cell is a melanocyte.
 10. The method of claim 1 wherein the test cell is a brain cell.
 11. A method of identifying a test cell as a cancer cell, comprising the step of: determining expression in a test cell of a gene product of an AXL receptor tyrosine kinase gene comprising a nucleotide sequence shown in SEQ ID NO:240, wherein the test cell is a breast epithelial cell; identifying the test cell as a cancer cell if an increase in said expression of at least two-fold relative to expression of the gene in a normal breast epithelial cell is observed.
 12. The method of claim 11 wherein the gene product is RNA.
 13. The method of claim 12 wherein expression is determined using at least one oligonucleotide probe.
 14. The method of claim 13 wherein expression is determined using at least two oligonucleotide probes.
 15. The method of claim 13 wherein the at least one oligonucleotide probe is immobilized on a solid support.
 16. The method of claim 15 wherein the at least one oligonucleotide probe is in an array.
 17. The method of claim 16 wherein the array contains more than 100 different probes in discrete locations.
 18. The method of claim 15 wherein the solid support is a gene chip.
 19. The method of claim 15 wherein the solid support is a bead.
 20. The method of claim 15 wherein the solid support is a microtiter well. 